Transmitting apparatus and signal processing method thereof

ABSTRACT

A transmitting apparatus and a receiving apparatus are provided. The transmitting apparatus includes: an encoder configured to generate a low density parity check (LDPC) codeword by performing LDPC encoding; an interleaver configured to interleave the LDPC codeword; and a modulator configured to modulate the interleaved LDPC codeword according to a modulation method to generate a modulation symbol. The interleaver includes a block interleaver formed of a plurality of columns each comprising a plurality of rows, and the block interleaver is configured to divide the plurality of columns into at least two parts and interleave the LDPC codeword.

CROSS-REFERENCE TO RELATED APPLICATION(S)

This application is a Continuation of U.S. Ser. No. 14/488,549 filed Sep. 17, 2014, which claims the benefit under 35 U.S.C. § 119 from U.S. Provisional Application No. 61/878,707 filed on Sep. 17, 2013 in the United States Patent and Trademark Office and Korean Patent Application No. 10-2014-0123657 filed on Sep. 17, 2014, the disclosures of which are incorporated herein by reference in their entirety.

BACKGROUND 1. Technical Field

Apparatuses and methods consistent with exemplary embodiments relate to a transmitting apparatus and a signal processing method thereof, and more particularly, to a transmitting apparatus which processes data and transmits the data, and a signal processing method thereof.

2. Description of the Related Art

In a communication/broadcasting system, link performance may greatly deteriorate due to various noises of channels, a fading phenomenon, and an inter-symbol interference (ISI). Therefore, in order to implement high digital communication/broadcasting systems requiring high data throughput and reliability, such as next-generation mobile communication, digital broadcasting, and portable Internet, there is a demand for a method for overcoming the noise, fading, and inter-symbol interference. To overcome the noise, etc., research on an error-correction code has been actively conducted in recent years as a method for effectively restoring distorted information and enhancing reliability of communication.

The Low Density Parity Check (LDPC) code which was first introduced by Gallager in the 1960s has been forgotten for a long time due to its difficulty and complexity in realizing by the level of technology at that time. However, as the turbo code which was suggested by Berrou, Glavieux, Thitimajshima in 1993 showed performance equivalent to the channel capacity of Shannon, the performance and characteristics of the turbo code were actively interpreted and many researches on channel encoding based on iterative decoding and graph were conducted. This leaded the re-research on the LDPC code in the late 1990's and it turned out that decoding by applying iterative decoding based on a sum-product algorithm on a Tanner graph corresponding to the LDPC code resulted in the performance equivalent to the channel capacity of Shannon.

When the LDPC code is transmitted by using a high order modulation scheme, performance depends on how codeword bits are mapped onto high order modulation bits. Therefore, there is a need for a method for mapping LDPC codeword bits onto high order modulation bits to obtain an LDPC code of good performance.

SUMMARY

One or more exemplary embodiments may overcome the above disadvantages and other disadvantages not described above. However, it is understood that one or more exemplary embodiment are not required to overcome the disadvantages described above, and may not overcome any of the problems described above.

One or more exemplary embodiments provide a transmitting apparatus which can map a bit included in a predetermined group from among a plurality of groups of a Low Density Parity Check (LDPC) codeword onto a predetermined bit of a modulation symbol, and transmit the bit, and a signal processing method thereof.

According to an aspect of an exemplary embodiment, there is provided a transmitting apparatus including: an encoder configured to generate a low density parity check (LDPC) codeword by performing LDPC encoding; an interleaver configured to interleave the LDPC codeword; and a modulator configured to modulate the interleaved LDPC codeword according to a modulation method to generate a modulation symbol, wherein the interleaver includes a block interleaver formed of a plurality of columns each including a plurality of rows, and wherein the block interleaver is configured to divide the plurality of columns into at least two parts and interleave the LDPC codeword.

The block interleaver may be configured to divide the plurality of columns into a first part and a second part, and to interleave by writing and reading the LDPC codeword in the first part and the second part in a same method.

The block interleaver may be configured to interleave by writing the LDPC codeword in the plurality of columns constituting each of the first part and the second part in a column direction and reading the plurality of columns constituting each of the first part and the second part in which the LDPC codeword is written in a row direction.

The block interleaver may be configured to divide the plurality of columns into a first part and a second part based on a number of columns constituting the block interleaver.

In each of the plurality of columns, the first part may be formed of as many rows as a number of bits included in at least some group which can be written in each of the plurality of columns in group units from among a plurality of groups constituting the LDPD codeword according to the number of columns constituting the block interleaver, and, in each of the plurality of columns, the second part may be formed of rows excluding as many rows as the number of bits included in the at least some group which can be written in each of the plurality of columns in group unit from rows constituting each of the plurality of columns.

The number of columns constituting the block interleaver may be determined according to the modulation method.

The block interleaver may be configured to interleave by writing at least some group which can be written in each of the plurality of columns in group units in each of the plurality of columns constituting the first part in the column direction, dividing the other groups excluding the at least some group from the plurality of groups and writing the divided groups in each of the plurality of columns constituting the second part in the column direction, and reading bits written in each of the plurality of columns constituting the first part and the second in the row direction.

The block interleaver may be configured to divide the other groups excluding the at least some group from the plurality of groups based on the number of columns constituting the block interleaver.

The interleaver may further include: a group interleaver configured to divide the LDPC codeword into the plurality of groups and rearrange an order of the plurality of groups in group units, and wherein the block interleaver is configured to interleave the plurality of groups the order of which has been rearranged.

The modulator may generate the modulation symbol using bits included in each of the plurality of groups.

According to an aspect of another exemplary embodiment, there is provided a method for processing a signal of a transmitting apparatus, the method including: generating an LDPC codeword by performing LDPC encoding; interleaving the LDPC codeword; and modulating the interleaved LDPC codeword according to a modulation method to generate a modulation symbol, wherein the interleaving uses a plurality of columns each including a plurality of rows, and includes dividing the plurality of columns into two at least parts and interleaving the LDPC codeword.

The interleaving may include dividing the plurality of columns into a first part and a second part, and interleaving by writing and reading the LDPC codeword in the first part and the second part in a same method.

The interleaving may include interleaving by writing the LDPC codeword in the plurality of columns constituting each of the first part and the second part in a column direction and reading the plurality of columns constituting each of the first part and the second part in which the LDPC codeword is written in a row direction.

The interleaving may include dividing the plurality of columns into a first part and a second part based on a number of columns.

In each of the plurality of columns, the first part may be formed of as many rows as a number of bits included in at least some group which can be written in each of the plurality of columns in group units from among a plurality of groups constituting the LDPD codeword according to the number of columns, and, in each of the plurality of columns, the second part may be formed of rows excluding as many rows as the number of bits included in the at least some group which can be written in each of the plurality of columns in group unit from rows constituting each of the plurality of columns.

The number of columns may be determined according to the modulation method.

The interleaving may include interleaving by writing at least some group which can be written in each of the plurality of columns in group units in each of the plurality of columns constituting the first part in the column direction, dividing the other groups excluding the at least some group from the plurality of groups and writing the divided groups in each of the plurality of columns constituting the second part in the column direction, and reading bits written in each of the plurality of columns constituting the first part and the second in the row direction.

The interleaving may include dividing the other groups excluding the at least some group from the plurality of groups based on the number of columns.

The method may further include: dividing the LDPC codeword into the plurality of groups and rearranging an order of the plurality of groups in group units, and the interleaving may include interleaving the plurality of groups the order of which has been rearranged.

The modulating may generate the modulation symbol using bits included in each of the plurality of groups.

According to various exemplary embodiments described above, improved decoding and receiving performance may be provided.

BRIEF DESCRIPTION OF THE DRAWINGS

The above and/or other aspects will be more apparent by describing in detail exemplary embodiments, with reference to the accompanying drawings, in which:

FIG. 1 is a block diagram to illustrate a configuration of a transmitting apparatus according to an exemplary embodiment;

FIGS. 2 and 3 are views to illustrate a configuration of a parity check matrix according to exemplary embodiments;

FIG. 4 is a block diagram to illustrate a configuration of an interleaver according to an exemplary embodiment;

FIGS. 5 to 7 are views illustrating a method for processing an LDPC codeword on a group basis according to exemplary embodiments;

FIGS. 8 to 11 are views to illustrate a configuration of a block interleaver and an interleaving method according to exemplary embodiments;

FIGS. 12 and 13 are views to illustrate an operation of a demultiplexer according to exemplary embodiments;

FIG. 14 is a view to illustrate an example of a uniform constellation modulation method according to an exemplary embodiment;

FIGS. 15 to 19 are views to illustrate an example of a non-uniform constellation modulation method according to exemplary embodiments;

FIG. 20 is a block diagram to illustrate a configuration of an interleaver according to another exemplary embodiment;

FIGS. 21 to 23 are views to illustrate a configuration of a block-row interleaver and an interleaving method according to exemplary embodiments;

FIG. 24 is a block diagram to illustrate a configuration of a receiving apparatus according to an exemplary embodiment;

FIGS. 25 and 27 are block diagrams to illustrate a configuration of a deinterleaver according to exemplary embodiments;

FIG. 26 is a view to illustrate a block deinterleaver according to an exemplary embodiment; and

FIG. 28 is a flowchart to illustrate a signal processing method according to an exemplary embodiment.

DETAILED DESCRIPTION OF THE EXEMPLARY EMBODIMENTS

Hereinafter, various exemplary embodiments will be described in greater detail with reference to the accompanying drawings.

In the following description, same reference numerals are used for the same elements when they are depicted in different drawings. The matters defined in the description, such as detailed construction and elements, are provided to assist in a comprehensive understanding of the exemplary embodiments. Thus, it is apparent that the exemplary embodiments can be carried out without those specifically defined matters. Also, functions or elements known in the related art are not described in detail since they would obscure the exemplary embodiments with unnecessary detail.

FIG. 1 is a block diagram to illustrate a configuration of a transmitting apparatus according to a first exemplary embodiment. Referring to FIG. 1, the transmitting apparatus 100 includes an encoder 110, an interleaver 120, and a modulator 130 (or a constellation mapper).

The encoder 110 generates a Low Density Parity Check (LDPC) codeword by performing LDPC encoding. The encoder 110 may include an LDPC encoder (not shown) to perform the LDPC encoding.

Specifically, the encoder 110 LDPC-encodes input bits to information word bits to generate the LDPC codeword which is formed of the information word bits and parity bits (that is, LDPC parity bits). Here, since an LDPC code for the LDPC encoding is a systematic code, the information word bits may be included in the LDPC codeword as they are.

The LDPC codeword is formed of the information word bits and the parity bits. For example, the LDPC codeword is formed of N_(ldpc) number of bits, and includes K_(ldpc) number of information word bits and N_(parity)=N_(ldpc)−K_(ldpc) number of parity bits.

In this case, the encoder 110 may generate the LDPC codeword by performing the LDPC encoding based on a parity check matrix. That is, since the LDPC encoding is a process for generating an LDPC codeword to satisfy H·C^(T)=0, the encoder 110 may use the parity check matrix when performing the LDPC encoding. Herein, H is a parity check matrix and C is an LDPC codeword.

For the LDPC encoding, the transmitting apparatus 100 may include a separate memory and may pre-store parity check matrices of various formats.

For example, the transmitting apparatus 100 may pre-store parity check matrices which are defined in Digital Video Broadcasting-Cable version 2 (DVB-C2), Digital Video Broadcasting-Satellite-Second Generation (DVB-S2), Digital Video Broadcasting-Second Generation Terrestrial (DVB-T2), etc., or may pre-store parity check matrices which are defined in the North America digital broadcasting standard system Advanced Television System Committee (ATSC) 3.0 standards, which are currently being established. However, this is merely an example and the transmitting apparatus 100 may pre-store parity check matrices of other formats in addition to these parity check matrices.

Hereinafter, a configuration of a parity check matrix will be explained in detail with reference to FIGS. 2 and 3.

First, referring to FIG. 2, a parity check matrix 200 is formed of an information word submatrix 210 corresponding to information word bits, and a parity submatrix 220 corresponding to parity bits. In the parity check matrix 200, elements other than elements with 1 have 0.

The information word submatrix 210 includes K_(ldpc) number of columns and the parity submatrix 220 includes N_(parity)=N_(ldpc)−K_(ldpc) number of columns. The number of rows of the parity check matrix 200 is identical to the number of columns of the parity submatrix 220, N_(parity)=N_(ldpc)−K_(ldpc).

In addition, in the parity check matrix 200, N_(ldpc) is a length of an LDPC codeword, K_(ldpc) is a length of information word bits, and N_(parity)=N_(ldpc)−K_(ldpc) is a length of parity bits. The length of the LDPC codeword, the information word bits, and the parity bits mean the number of bits included in each of the LDPC codeword, the information bits, and the parity bits.

Hereinafter, the configuration of the information word submatrix 210 and the parity submatrix 220 will be explained in detail.

The information word submatrix 210 includes K_(ldpc) number of columns (that is, 0^(th) column to (K_(ldpc)−1)^(th) column), and follows the following rules:

First, M number of columns from among K_(ldpc) number of columns of the information word submatrix 210 belong to the same group, and K_(ldpc) number of columns is divided into K_(ldpc)/M number of column groups. In each column group, a column is cyclic-shifted from an immediately previous column by Q_(ldpc) or Q_(ldpc) number of bits.

Herein, M is an interval at which a pattern of a column group, which includes a plurality of columns, is repeated in the information word submatrix 210 (e.g., M=360), and Q_(ldpc) is a size by which one column is cyclic-shifted from an immediately previous column in a same column group in the information word submatrix 210. M and Q_(ldpc) are integers and are determined to satisfy Q_(ldpc)=(N_(ldpc)−K_(ldpc))/M. In this case, K_(ldpc)/M is also an integer. M and Q_(ldpc) may have various values according to a length of the LDPC codeword and a code rate.

For example, when M=360 and the length of the LDPC codeword, N_(ldpc), is 64800, Q_(ldpc) may be defined as in table 1 presented below, and, when M=360 and the length N_(ldpc) of the LDPC codeword is 16200, Q_(ldpc) may be defined as in table 2 presented below.

TABLE 1 Code Rate N_(ldpc) M Q_(ldpc) 5/15 64800 360 120 6/15 64800 360 108 7/15 64800 360 96 8/15 64800 360 84 9/15 64800 360 72 10/15  64800 360 60 11/15  64800 360 48 12/15  64800 360 36 13/15  64800 360 24

TABLE 2 Code Rate N_(ldpc) M Q_(ldpc) 5/15 16200 360 30 6/15 16200 360 27 7/15 16200 360 24 8/15 16200 360 21 9/15 16200 360 18 10/15  16200 360 15 11/15  16200 360 12 12/15  16200 360 9 13/15  16200 360 6

Second, when the degree of the 0^(th) column of the i^(th) column group (i=0, 1, . . . , K_(ldpc)/M−1) is D_(i) (herein, the degree is the number of value 1 existing in each column and all columns belonging to the same column group have the same degree), and a position (or an index) of each row where 1 exists in the 0^(th) column of the i^(th) column group is R_(i,0) ⁽⁰⁾,R_(i,0) ⁽¹⁾, . . . ,R_(i,0) ^((D) ^(i) ⁻¹⁾, an index R_(i,j) ^((k)) of a row where k^(th) weight−1 is located in the j^(th) column in the i^(th) column group (that is, an index of a row where k^(th) 1 is located in the j^(th) column in the i^(th) column group) is determined by following Equation 1:

R _(i,j) ^((k)) =R _(i,(j−1)) ^((k)) +Q _(ldpc) mod(N _(ldpc) −K _(ldpc)) (1)

where k=0, 1, 2, . . . D₁−1; i=0, 1, . . . , K_(ldpc)/M−1; and j=1, 2, . . . , M−1.

Equation 1 can be expressed as following Equation 2:

R _(i,j) ^((k)) ={R _(i,0) ^((k))+(j mod M)×Q _(ldpc)} mod(N _(ldpc) −K _(ldpc))   (2)

where k=0, 1, 2, . . . D_(i)−1; i=0, 1, . . . , K_(ldpc)/M−1; and j=1, 2, . . . , M−1.

In the above equations, R_(i,j) ^((k)) is an index of a row where k^(th) weight−1 is located in the j^(th) column in the i^(th) column group, N_(ldpc) is a length of an LDPC codeword, K_(ldpc) is a length of information word bits, D_(i) is a degree of columns belonging to the i^(th) column group, M is the number of columns belonging to a single column group, and Q_(ldpc) is a size by which each column in the column group is cyclic-shifted.

As a result, referring to these equations, when only R_(i,0) ^((k)) is known, the index R_(i,j) ^((k)) of the row where the k^(th) weight−1 is located in the j^(th) column in the i^(th) column group can be known. Therefore, when the index value of the row where the k^(th) weight−1 is located in the first column of each column group is stored, a position of column and row where weight−1 is located in the parity check matrix 200 having the configuration of FIG. 2 (that is, in the information word submatrix 210 of the parity check matrix 200) can be known.

According to the above-described rules, all of the columns belonging to the i^(th) column group have the same degree D_(i). Accordingly, the LDPC codeword which stores information on the parity check matrix according to the above-described rules may be briefly expressed as follows.

For example, when N_(ldpc) is 30, K_(ldpc) is 15, and Q_(ldpc) is 3, position information of the row where weight−1 is located in the 0^(th) column of the three column groups may be expressed by a sequence of Equations 3 and may be referred to as “weight−1 position sequence”.

R _(1,0) ⁽¹⁾=1,R _(1,0) ⁽²⁾=2,R _(1,0) ⁽³⁾=8,R _(1,0) ⁽⁴⁾=10,

R _(2,0) ⁽¹⁾=0,R _(2,0) ⁽²⁾=9,R _(2,0) ⁽³⁾=13,

R _(3,0) ⁽¹⁾=0,R _(3,0) ⁽²⁾=14.   (3),

where R_(i,j) ^((k)) is an index of a row where k^(th) weight−1 is located in the j^(th) column in the i^(th) column group.

The weight−1 position sequence like Equation 3 which expresses an index of a row where 1 is located in the 0^(th) column of each column group may be briefly expressed as in Table 3 presented below:

TABLE 3 1 2 8 10 0 9 13 0 14

Table 3 shows positions of elements having weight−1, that is, the value 1, in the parity check matrix, and the i^(th) weight−1 position sequence is expressed by indexes of rows where weight−1 is located in the 0^(th) column belonging to the i^(th) column group.

The information word submatrix 210 of the parity check matrix according to an exemplary embodiment may be defined as in Tables 4 to 26 presented below, based on the above descriptions.

Specifically, Tables 4 to 26 show indexes of rows where 1 is located in the 0^(th) column of the i^(th) column group of the information word submatrix 210. That is, the information word submatrix 210 is formed of a plurality of column groups each including M number of columns, and positions of 1 in the 0^(th) column of each of the plurality of column groups may be defined by Tables 4 to 26.

Herein, the indexes of the rows where 1 is located in the 0^(th) column of the i^(th) column group mean “addresses of parity bit accumulators”. The “addresses of parity bit accumulators” have the same meaning as defined in the DVB-C2/S2/T2 standards or the ATSC 3.0 standards which are currently being established, and thus, a detailed explanation thereof is omitted.

For example, when the length N_(ldpc) of the LDPC codeword is 16200, the code rate R is 5/15, and M is 360, the indexes of the rows where 1 is located in the 0^(th) column of the i^(th) column group of the information word submatrix 210 are as shown in Table 4 presented below:

TABLE 4 Index of row where 1 is located in the 0th column of the i ith column group 0 245 449 491 980 1064 1194 1277 1671 2026 3186 4399 4900 5283 5413 5558 6570 7492 7768 7837 7984 8306 8483 8685 9357 9642 10045 10179 10261 10338 10412 1 1318 1584 1682 1860 1954 2000 2062 3387 3441 3879 3931 4240 4302 4446 4603 5117 5588 5675 5793 5955 6097 6221 6449 6616 7218 7394 9535 9896 10009 10763 2 105 472 785 911 1168 1450 2550 2851 3277 3624 4128 4460 4572 4669 4783 5102 5133 5199 5905 6647 7028 7086 7703 8121 8217 9149 9304 9476 9736 9884 3 1217 5338 5737 8334 4 855 994 2979 9443 5 7506 7811 9212 9982 6 848 3313 3380 3990 7 2095 4113 4620 9946 8 1488 2396 6130 7483 9 1002 2241 7067 10418 10 2008 3199 7215 7502 11 1161 7705 8194 8534 12 2316 4803 8649 9359 13 125 1880 3177 14 1141 8033 9072

In another example, when the length N_(ldpc) of the LDPC codeword is 16200, the code rate R is 6/15, and M is 360, the indexes of the rows where 1 is located in the 0^(th) column of the i^(th) column group of the information word submatrix 210 are as shown in Table 5 presented below:

TABLE 5 Index of row where 1 is located in the 0th column of i the ith column group 0 13 88 136 188 398 794 855 918 954 1950 2762 2837 2847 4209 4342 5092 5334 5498 5731 5837 6150 6942 7127 7402 7936 8235 8307 8600 9001 9419 9442 9710 1 619 792 1002 1148 1528 1533 1925 2207 2766 3021 3267 3593 3947 4832 4873 5109 5488 5882 6079 6097 6276 6499 6584 6738 6795 7550 7723 7786 8732 9060 9270 9401 2 499 717 1551 1791 2535 3135 3582 3813 4047 4309 5126 5186 5219 5716 5977 6236 6406 6586 6591 7085 7199 7485 7726 7878 8027 8066 8425 8802 9309 9464 9553 9671 3 658 4058 7824 8512 4 3245 4743 8117 9369 5 465 6559 8112 9461 6 975 2368 4444 6095 7 4128 5993 9182 9473 8 9 3822 5306 5320 9 4 8311 9571 9669 10 13 8122 8949 9656 11 3353 4449 5829 8053 12 7885 9118 9674 13 7575 9591 9670 14 431 8123 9271 15 4228 7587 9270 16 8847 9146 9556 17 11 5213 7763

In another example, when the length N_(ldpc) of the LDPC codeword is 16200, the code rate R is 7/15, and M is 360, the indexes of the rows where 1 is located in the 0^(th) column of the i^(th) column group of the information word submatrix 210 are as shown in Table 6 presented below:

TABLE 6 Index of row where 1 is located in the 0th column of i the ith column group 0 432 655 893 942 1285 1427 1738 2199 2441 2565 2932 3201 4144 4419 4678 4963 5423 5922 6433 6564 6656 7478 7514 7892 1 220 453 690 826 1116 1425 1488 1901 3119 3182 3568 3800 3953 4071 4782 5038 5555 6836 6871 7131 7609 7850 8317 8443 2 300 454 497 930 1757 2145 2314 2372 2467 2819 3191 3256 3699 3984 4538 4965 5461 5742 5912 6135 6649 7636 8078 8455 3 24 65 565 609 990 1319 1394 1465 1918 1976 2463 2987 3330 3677 4195 4240 4947 5372 6453 6950 7066 8412 8500 8599 4 1373 4668 5324 7777 5 189 3930 5766 6877 6 3 2961 4207 5747 7 1108 4768 6743 7106 8 1282 2274 2750 6204 9 2279 2587 2737 6344 10 2889 3164 7275 8040 11 133 2734 5081 8386 12 437 3203 7121 13 4280 7128 8490 14 619 4563 6206 15 2799 6814 6991 16 244 4212 5925 17 1719 7657 8554 18 53 1895 6685 19 584 5420 6856 20 2958 5834 8103

In another example, when the length N_(ldpc) of the LDPC codeword is 16200, the code rate R is 8/15, and M is 360, the indexes of the rows where 1 is located in the 0^(th) column of the i^(th) column group of the information word submatrix 210 are as shown in Table 7, 8 or 9 presented below:

TABLE 7 Index of row where 1 is located in the 0th column of i the ith column group 0 32 384 430 591 1296 1976 1999 2137 2175 3638 4214 4304 4486 4662 4999 5174 5700 6969 7115 7138 7189 1 1788 1881 1910 2724 4504 4928 4973 5616 5686 5718 5846 6523 6893 6994 7074 7100 7277 7399 7476 7480 7537 2 2791 2824 2927 4196 4298 4800 4948 5361 5401 5688 5818 5862 5969 6029 6244 6645 6962 7203 7302 7454 7534 3 574 1461 1826 2056 2069 2387 2794 3349 3366 4951 5826 5834 5903 6640 6762 6786 6859 7043 7418 7431 7554 4 14 178 675 823 890 930 1209 1311 2898 4339 4600 5203 6485 6549 6970 7208 7218 7298 7454 7457 7462 5 4075 4188 7313 7553 6 5145 6018 7148 7507 7 3198 4858 6983 7033 8 3170 5126 5625 6901 9 2839 6093 7071 7450 10 11 3735 5413 11 2497 5400 7238 12 2067 5172 5714 13 1889 7173 7329 14 1795 2773 3499 15 2695 2944 6735 16 3221 4625 5897 17 1690 6122 6816 18 5013 6839 7358 19 1601 6849 7415 20 2180 7389 7543 21 2121 6838 7054 22 1948 3109 5046 23 272 1015 7464

TABLE 8 Index of row where 1 is located in the 0th column of i the ith column group 0 5 519 825 1871 2098 2478 2659 2820 3200 3294 3650 3804 3949 4426 4460 4503 4568 4590 4949 5219 5662 5738 5905 5911 6160 6404 6637 6708 6737 6814 7263 7412 1 81 391 1272 1633 2062 2882 3443 3503 3535 3908 4033 4163 4490 4929 5262 5399 5576 5768 5910 6331 6430 6844 6867 7201 7274 7290 7343 7350 7378 7387 7440 7554 2 105 975 3421 3480 4120 4444 5957 5971 6119 6617 6761 6810 7067 7353 3 6 138 485 1444 1512 2615 2990 3109 5604 6435 6513 6632 6704 7507 4 20 858 1051 2539 3049 5162 5308 6158 6391 6604 6744 7071 7195 7238 5 1140 5838 6203 6748 6 6282 6466 6481 6638 7 2346 2592 5436 7487 8 2219 3897 5896 7528 9 2897 6028 7018 10 1285 1863 5324 11 3075 6005 6466 12 5 6020 7551 13 2121 3751 7507 14 4027 5488 7542 15 2 6012 7011 16 3823 5531 5687 17 1379 2262 5297 18 1882 7498 7551 19 3749 4806 7227 20 2 2074 6898 21 17 616 7482 22 9 6823 7480 23 5195 5880 7559

TABLE 9 Index of row where 1 is located in the 0th column of i the ith column group 0 6 243 617 697 1380 1504 1864 1874 1883 2075 2122 2439 2489 3076 3715 3719 3824 4028 4807 5006 5196 5532 5688 5881 6216 6899 7000 7118 7284 7412 7417 7523 1 0 6 17 20 105 1279 2443 2523 2800 3458 3684 4257 4799 4819 5499 5665 5810 5927 6169 6536 6617 6669 7069 7127 7132 7158 7164 7230 7320 7393 7396 7465 2 2 6 12 15 2033 2125 3352 3382 5931 7024 7143 7358 7391 7504 3 5 17 1725 1932 3277 4781 4888 6025 6374 7001 7139 7510 7524 7548 4 4 19 101 1493 4111 4163 4599 6517 6604 6948 6963 7008 7280 7319 5 8 28 2289 5025 6 5505 5693 6844 7552 7 9 3441 7424 7533 8 917 1816 3540 4552 9 256 6362 6868 10 2125 3144 5576 11 3443 5553 7201 12 2219 3897 4541 13 6331 6481 7224 14 7 1444 5568 15 81 1325 3345 16 778 2726 7316 17 3512 6462 7259 18 768 3751 6028 19 4665 7130 7452 20 2375 6814 7450 21 7073 7209 7483 22 2592 6466 7018 23 3716 5838 7547

In another example, when the length N_(ldpc) of the LDPC codeword is 16200, the code rate R is 9/15, and M is 360, the indexes of the rows where 1 is located in the 0^(th) column of the i^(th) column group of the information word submatrix 210 are as shown in Table 10 presented below:

TABLE 10 Index of row where 1 is located in the 0th column of i the ith column group 0 350 462 1291 1383 1821 2235 2493 3328 3353 3772 3872 3923 4259 4426 4542 4972 5347 6217 6246 6332 6386 1 177 869 1214 1253 1398 1482 1737 2014 2161 2331 3108 3297 3438 4388 4430 4456 4522 4783 5273 6037 6395 2 347 501 658 966 1622 1659 1934 2117 2527 3168 3231 3379 3427 3739 4218 4497 4894 5000 5167 5728 5975 3 319 398 599 1143 1796 3198 3521 3886 4139 4453 4556 4636 4688 4753 4986 5199 5224 5496 5698 5724 6123 4 162 257 304 524 945 1695 1855 2527 2780 2902 2958 3439 3484 4224 4769 4928 5156 5303 5971 6358 6477 5 807 1695 2941 4276 6 2652 2857 4660 6358 7 329 2100 2412 3632 8 1151 1231 3872 4869 9 1561 3565 5138 5303 10 407 794 1455 11 3438 5683 5749 12 1504 1985 3563 13 440 5021 6321 14 194 3645 5923 15 1217 1462 6422 16 1212 4715 5973 17 4098 5100 5642 18 5512 5857 6226 19 2583 5506 5933 20 784 1801 4890 21 4734 4779 4875 22 938 5081 5377 23 127 4125 4704 24 1244 2178 3352 25 3659 6350 6465 26 1686 3464 4336

In another example, when the length N_(ldpc) of the LDPC codeword is 16200, the code rate R is 10/15, and M is 360, the indexes of the rows where 1 is located in the 0^(th) column of the i^(th) column group of the information word submatrix 210 are as shown in Table 11 or 12 presented below:

TABLE 11 Index of row where 1 is located in the 0th column of i the ith column group 0 76 545 1005 1029 1390 1970 2525 2971 3448 3845 4088 4114 4163 4373 4640 4705 4970 5094 1 14 463 600 1676 2239 2319 2326 2815 2887 4278 4457 4493 4597 4918 4989 5038 5261 5384 2 451 632 829 1006 1530 1723 2205 2587 2801 3041 3849 4382 4595 4727 5006 5156 5224 5286 3 211 265 1293 1777 1926 2214 2909 2957 3178 3278 3771 4547 4563 4737 4879 5068 5232 5344 4 6 2901 3925 5384 5 2858 4152 5006 5202 6 9 1232 2063 2768 7 7 11 2781 3871 8 12 2161 2820 4078 9 3 3510 4668 5323 10 253 411 3215 5241 11 3919 4789 5040 5302 12 12 5113 5256 5352 13 9 1461 4004 5241 14 1688 3585 4480 5394 15 8 2127 3469 4360 16 2827 4049 5084 5379 17 1770 3331 5315 5386 18 1885 2817 4900 5088 19 2568 3854 4660 20 1604 3565 5373 21 2317 4636 5156 22 2480 2816 4094 23 14 4518 4826 24 127 1192 3872 25 93 2282 3663 26 2962 5085 5314 27 2078 4277 5089 28 9 5280 5292 29 50 2847 4742

TABLE 12 Index of row where 1 is i located in the 0th column of the ith column group 0 446 449 544 788 992 1389 1800 1933 2461 2975 3186 3442 3733 3773 4076 4308 4323 4605 4882 5034 5080 5135 5146 5269 5307 1 25 113 139 147 307 1066 1078 1572 1773 1957 2143 2609 2642 2901 3371 3414 3935 4141 4165 4271 4520 4754 4971 5160 5179 2 341 424 1373 1559 1953 2577 2721 3257 3706 4025 4273 4689 4995 5005 3 442 465 1892 2274 2292 2999 3156 3308 3883 4084 4316 4636 4743 5200 4 22 1809 2406 3332 3359 3430 3466 4610 4638 5224 5280 5288 5337 5381 5 29 1203 1444 1720 1836 2138 2902 3601 3642 4138 4269 4457 4965 5315 6 1138 2493 3852 4802 7 3050 5361 5396 8 278 399 4810 9 1200 3577 4904 10 1705 2811 3448 11 2180 4242 5336 12 4539 5069 5363 13 3318 3645 4427 14 2902 5134 5176 15 5123 5130 5229 16 47 4474 5356 17 2399 3981 5067 18 2377 2465 5080 19 2413 2471 5328 20 2502 4911 5329 21 4770 5139 5356 22 3263 4000 4022 23 648 2015 4867 24 311 2309 4063 25 1284 3246 3740 26 7 1080 3820 27 1261 2408 4608 28 3838 4076 4842 29 2294 4592 5254

In another example, when the length N_(ldpc) of the LDPC codeword is 16200, the code rate R is 11/15, and M is 360, the indexes of the rows where 1 is located in the 0^(th) column of the i^(th) column group of the information word submatrix 210 are as shown in Table 13 presented below:

TABLE 13 Index of row where 1 is i located in the 0th column of the ith column group 0 108 297 703 742 1345 1443 1495 1628 1812 2341 2559 2669 2810 2877 3442 3690 3755 3904 4264 1 180 211 477 788 824 1090 1272 1578 1685 1948 2050 2195 2233 2546 2757 2946 3147 3299 3544 2 627 741 1135 1157 1226 1333 1378 1427 1454 1696 1757 1772 2099 2208 2592 3354 3580 4066 4242 3 9 795 959 989 1006 1032 1135 1209 1382 1484 1703 1855 1985 2043 2629 2845 3136 3450 3742 4 230 413 801 829 1108 1170 1291 1759 1793 1827 1976 2000 2423 2466 2917 3010 3600 3782 4143 5 56 142 236 381 1050 1141 1372 1627 1985 2247 2340 3023 3434 3519 3957 4013 4142 4164 4279 6 298 1211 2548 3643 7 73 1070 1614 1748 8 1439 2141 3614 9 284 1564 2629 10 607 660 855 11 1195 2037 2753 12 49 1198 2562 13 296 1145 3540 14 1516 2315 2382 15 154 722 4016 16 759 2375 3825 17 162 194 1749 18 2335 2422 2632 19 6 1172 2583 20 726 1325 1428 21 985 2708 2769 22 255 2801 3181 23 2979 3720 4090 24 208 1428 4094 25 199 3743 3757 26 1229 2059 4282 27 458 1100 1387 28 1199 2481 3284 29 1161 1467 4060 30 959 3014 4144 31 2666 3960 4125 32 2809 3834 4318

In another example, when the length N_(ldpc) of the LDPC codeword is 16200, the code rate R is 12/15, and M is 360, the indexes of the rows where 1 is located in the 0^(th) column of the i^(th) column group of the information word submatrix 210 are as shown in Table 14 or 15 presented below:

TABLE 14 Index of row where 1 is i located in the 0th column of the ith column group 0 3 394 1014 1214 1361 1477 1534 1660 1856 2745 2987 2991 3124 3155 1 59 136 528 781 803 928 1293 1489 1944 2041 2200 2613 2690 2847 2 155 245 311 621 1114 1269 1281 1783 1995 2047 2672 2803 2885 3014 3 79 870 974 1326 1449 1531 2077 2317 2467 2627 2811 3083 3101 3132 4 4 582 660 902 1048 1482 1697 1744 1928 2628 2699 2728 3045 3104 5 175 395 429 1027 1061 1068 1154 1168 1175 2147 2359 2376 2613 2682 6 1388 2241 3118 3148 7 143 506 2067 3148 8 1594 2217 2705 9 398 988 2551 10 1149 2588 2654 11 678 2844 3115 12 1508 1547 1954 13 1199 1267 1710 14 2589 3163 3207 15 1 2583 2974 16 2766 2897 3166 17 929 1823 2742 18 1113 3007 3239 19 1753 2478 3127 20 0 509 1811 21 1672 2646 2984 22 965 1462 3230 23 3 1077 2917 24 1183 1316 1662 25 968 1593 3239 26 64 1996 2226 27 1442 2058 3181 28 513 973 1058 29 1263 3185 3229 30 681 1394 3017 31 419 2853 3217 32 3 2404 3175 33 2417 2792 2854 34 1879 2940 3235 35 647 1704 3060

TABLE 15 Index of row where 1 is i located in the 0th column of the ith column group 0 69 170 650 1107 1190 1250 1309 1486 1612 1625 2091 2416 2580 2673 2921 2995 3175 3234 1 299 652 680 732 1197 1394 1779 1848 1885 2206 2266 2286 2706 2795 3206 3229 2 107 133 351 640 805 1136 1175 1479 1817 2068 2139 2586 2809 2855 2862 2930 3 75 458 508 546 584 624 875 1948 2363 2471 2574 2715 3008 3052 3070 3166 4 0 7 897 1664 1981 2172 2268 2272 2364 2873 2902 3016 3020 3121 3203 3236 5 121 399 550 1157 1216 1326 1789 1838 1888 2160 2537 2745 2949 3001 3020 3152 6 1497 2022 2726 2871 7 872 2320 2504 3234 8 851 1684 3210 3217 9 1807 2918 3178 10 671 1203 2343 11 405 490 3212 12 1 1474 3235 13 527 1224 2139 14 3 1997 2072 15 833 2366 3183 16 385 1309 3196 17 1343 2691 3153 18 1815 2048 2394 19 812 2055 2926 20 166 826 2807 21 1 493 2961 22 2218 3032 3153 23 2099 2885 3228 24 1214 2677 3216 25 2292 2422 2835 26 574 2138 3053 27 576 1409 1912 28 354 1631 3142 29 3211 3228 3239 30 1335 2938 3184 31 729 995 1520 32 537 3115 3233 33 4 2631 3231 34 1130 2851 3030 35 1136 2728 3203

In another example, when the length N_(ldpc) of the LDPC codeword is 16200, the code rate R is 13/15, and M is 360, the indexes of the rows where 1 is located in the 0^(th) column of the i^(th) column group of the information word submatrix 210 are as shown in Table 16 presented below:

TABLE 16 Index of row where 1 is i located in the 0th column of the ith column group 0 37 144 161 199 220 496 510 589 731 808 834 965 1249 1264 1311 1377 1460 1520 1598 1707 1958 2055 2099 2154 1 20 27 165 462 546 583 742 796 1095 1110 1129 1145 1169 1190 1254 1363 1383 1463 1718 1835 1870 1879 2108 2128 2 288 362 463 505 638 691 745 861 1006 1083 1124 1175 1247 1275 1337 1353 1378 1506 1588 1632 1720 1868 1980 2135 3 405 464 478 511 566 574 641 766 785 802 836 996 1128 1239 1247 1449 1491 1537 1616 1643 1668 1950 1975 2149 4 86 192 245 357 363 374 700 713 852 903 992 1174 1245 1277 1342 1369 1381 1417 1463 1712 1900 1962 2053 2118 5 101 327 378 550 6 186 723 1318 1550 7 118 277 504 1835 8 199 407 1776 1965 9 387 1253 1328 1975 10 62 144 1163 2017 11 100 475 572 2136 12 431 865 1568 2055 13 283 640 981 1172 14 220 1038 1903 2147 15 483 1318 1358 2118 16 92 961 1709 1810 17 112 403 1485 2042 18 431 1110 1130 1365 19 587 1005 1206 1588 20 704 1113 1943 21 375 1487 2100 22 1507 1950 2110 23 962 1613 2038 24 554 1295 1501 25 488 784 1446 26 871 1935 1964 27 54 1475 1504 28 1579 1617 2074 29 1856 1967 2131 30 330 1582 2107 31 40 1056 1809 32 1310 1353 1410 33 232 554 1939 34 168 641 1099 35 333 437 1556 36 153 622 745 37 719 931 1188 38 237 638 1607

In another example, when the length N_(ldpc) of the LDPC codeword is 64800, the code rate R is 6/15, and M is 360, the indexes of the rows where 1 is located in the 0^(th) column of the i^(th) column group of the information word submatrix 210 are as shown in Table 17 presented below:

TABLE 17 i Index of row where 1 is located in the 0th column of the ith column group 0 1606 3402 4961 6751 7132 11516 12300 12482 12592 13342 13764 14123 21576 23946 24533 25376 25667 26836 31799 34173 35462 36153 36740 37085 37152 37468 37658 1 4621 5007 6910 8732 9757 11508 13099 15513 16335 18052 19512 21319 23663 25628 27208 31333 32219 33003 33239 33447 36200 36473 36938 37201 37283 37495 38642 2 16 1094 2020 3080 4194 5098 5631 6877 7889 8237 9804 10067 11017 11366 13136 13354 15379 18934 20199 24522 26172 28666 30386 32714 36390 37015 37162 3 700 897 1708 6017 6490 7372 7825 9546 10398 16605 18561 18745 21625 22137 23693 24340 24966 25015 26995 28586 28895 29687 33938 34520 34858 37056 38297 4 159 2010 2573 3617 4452 4958 5556 5832 6481 8227 9924 10836 14954 15594 16623 18065 19249 22394 22677 23408 23731 24076 24776 27007 28222 30343 38371 5 3118 3545 4768 4992 5227 6732 8170 9397 10522 11508 15536 20218 21921 28599 29445 29758 29968 31014 32027 33685 34378 35867 36323 36728 36870 38335 38623 6 1264 4254 6936 9165 9486 9950 10861 11653 13697 13961 15164 15665 18444 19470 20313 21189 24371 26431 26999 28086 28251 29261 31981 34015 35850 36129 37186 7 111 1307 1628 2041 2524 5358 7988 8191 10322 11905 12919 14127 15515 15711 17061 19024 21195 22902 23727 24401 24608 25111 25228 27338 35398 37794 38196 8 961 3035 7174 7948 13355 13607 14971 18189 18339 18665 18875 19142 20615 21136 21309 21758 23366 24745 25849 25982 27583 30006 31118 32106 36469 36583 37920 9 2990 3549 4273 4808 5707 6021 6509 7456 8240 10044 12262 12660 13085 14750 15680 16049 21587 23997 25803 28343 28693 34393 34860 35490 36021 37737 38296 10 955 4323 5145 6885 8123 9730 11840 12216 19194 20313 23056 24248 24830 25268 26617 26801 28557 29753 30745 31450 31973 32839 33025 33296 35710 37366 37509 11 264 605 4181 4483 5156 7238 8863 10939 11251 12964 16254 17511 20017 22395 22818 23261 23422 24064 26329 27723 28186 30434 31956 33971 34372 36764 38123 12 520 2562 2794 3528 3860 4402 5676 6963 8655 9018 9783 11933 16336 17193 17320 19035 20606 23579 23769 24123 24966 27866 32457 34011 34499 36620 37526 13 10106 10637 10906 34242 14 1856 15100 19378 21848 15 943 11191 27806 29411 16 4575 6359 13629 19383 17 4476 4953 18782 24313 18 5441 6381 21840 35943 19 9638 9763 12546 30120 20 9587 10626 11047 25700 21 4088 15298 28768 35047 22 2332 6363 8782 28863 23 4625 4933 28298 30289 24 3541 4918 18257 31746 25 1221 25233 26757 34892 26 8150 16677 27934 30021 27 8500 25016 33043 38070 28 7374 10207 16189 35811 29 611 18480 20064 38261 30 25416 27352 36089 38469 31 1667 17614 25839 32776 32 4118 12481 21912 37945 33 5573 13222 23619 31271 34 18271 26251 27182 30587 35 14690 26430 26799 34355 36 13688 16040 20716 34558 37 2740 14957 23436 32540 38 3491 14365 14681 36858 39 4796 6238 25203 27854 40 1731 12816 17344 26025 41 19182 21662 23742 27872 42 6502 13641 17509 34713 43 12246 12372 16746 27452 44 1589 21528 30621 34003 45 12328 20515 30651 31432 46 3415 22656 23427 36395 47 632 5209 25958 31085 48 619 3690 19648 37778 49 9528 13581 26965 36447 50 2147 26249 26968 28776 51 15698 18209 30683 52 1132 19888 34111 53 4608 25513 38874 54 475 1729 34100 55 7348 32277 38587 56 182 16473 33082 57 3865 9678 21265 58 4447 20151 27618 59 6335 14371 38711 60 704 9695 28858 61 4856 9757 30546 62 1993 19361 30732 63 756 28000 29138 64 3821 24076 31813 65 4611 12326 32291 66 7628 21515 34995 67 1246 13294 30068 68 6466 33233 35865 69 14484 23274 38150 70 21269 36411 37450 71 23129 26195 37653

In another example, when the length N_(ldpc) of the LDPC codeword is 64800, the code rate R is 7/15, and M is 360, the indexes of the rows where 1 is located in the 0^(th) column of the i^(th) column group of the information word submatrix 210 are as shown in Table 18 presented below:

TABLE 18 i Index of row where 1 is located in the 0th column of the ith column group 0 13 127 927 930 1606 2348 3361 3704 5194 6327 7843 8081 8615 12199 13947 15317 15774 16289 16687 17122 20468 21057 21853 22414 23829 23885 25452 28072 28699 28947 30289 31672 32470 1 36 53 60 86 93 407 3975 4478 5884 6578 7599 7613 7696 9573 11010 11183 11233 13750 17182 17860 20181 23974 24195 25089 25787 25892 26121 30880 32989 33383 33626 34153 34520 2 27 875 2693 3435 3682 6195 6227 6711 7629 8005 9081 11052 11190 11443 14832 17431 17756 17998 18254 18632 22234 22880 23562 23647 27092 29035 29620 30336 33492 33906 33960 34337 34474 3 10 722 1241 3558 5490 5508 6420 7128 12386 12847 12942 15305 15592 16799 18033 19134 20713 20870 21589 26380 27538 27577 27971 29744 32344 32347 32673 32892 33018 33674 33811 34253 34511 4 6 24 72 2552 3171 5179 11519 12484 13096 13282 15226 18193 19995 25166 25303 25693 26821 29193 30666 31952 33137 33187 33190 33319 33653 33950 34062 34255 34292 34365 34433 34443 34527 5 1 12 26 29 85 1532 3870 6763 7533 7630 8022 8857 11667 11919 14987 16133 20999 21830 23522 24160 27671 28451 30618 31556 31894 33436 33543 34146 34197 34313 34437 34480 34550 6 13 44 2482 5068 8153 13233 13728 14548 17278 20027 21273 22112 22376 24799 29175 7 26 50 8325 8891 12816 15672 15933 24049 30372 31245 33194 33238 33934 34093 34547 8 1412 6334 7945 8866 10886 14521 17224 23693 25160 29267 31337 31893 32346 33195 33687 9 27 47 14505 14786 18416 19963 23250 23475 27275 27921 28090 33985 34371 34374 34512 10 16 31 4924 7028 10240 12380 13479 16405 20197 27989 28084 32440 33996 34090 34435 11 17 57 95 6786 7427 7548 10452 13714 25632 30647 33054 34195 34237 34304 34447 12 4 62 331 10220 10518 10575 18401 19286 28718 30521 30968 31329 31848 32614 34343 13 42 79 4682 4747 7335 11487 17405 18089 19470 22457 33433 34373 34471 34519 34540 14 27 65 4911 10752 14803 24122 24531 25322 29130 30081 31280 32050 32693 34435 34508 15 24 29 2107 2152 5271 11032 14001 14902 21705 23126 31276 33946 34372 34380 34469 16 16 62 72 7470 14839 15299 15894 17716 18068 24959 25024 33343 34186 34398 34429 17 37 56 70 2089 10016 11316 14652 15665 17202 19804 19847 30498 33938 34126 34391 18 68 963 2099 9596 17606 19249 21839 27437 29901 30714 33060 33456 34347 34498 34527 19 6 69 1845 2504 7189 8603 10379 11421 13742 15757 16857 20642 28039 32833 34270 20 2235 15032 31823 21 4737 33978 34504 22 2 20263 30373 23 923 18929 25743 24 4587 22945 28380 25 22094 26147 34544 26 5177 20758 26476 27 8938 17291 27352 28 5286 24717 29331 29 71 16442 32683 30 81 22810 28015 31 14112 14419 29708 32 4156 7522 23358 33 12850 20777 28294 34 14692 31178 34238 35 3447 12356 21997 36 6098 15443 33447 37 5947 11648 21719 38 72 8695 18421 39 2173 18978 27232 40 13656 18222 19869 41 49 24684 33849 42 84 13870 18354 43 54 10089 10516 44 8035 18741 23775 45 7553 13539 25652 46 9116 26724 27525 47 22960 24382 26185 48 17384 24749 26726 49 12197 18965 32473 50 95 23126 26909 51 19327 31338 34320 52 9843 34130 34381 53 4031 9940 22329 54 58 31795 34468 55 103 17411 25220 56 26 4338 24625 57 9758 34395 34531 58 2186 17077 27646 59 9156 19462 34059 60 6 59 29352 61 16316 29453 34128 62 16244 32865 34517 63 918 22159 29265 64 13612 19465 20671 65 1 8261 8849 66 11214 28864 32696 67 11513 27595 34479 68 11895 21430 34524 69 82 5535 10552 70 66 15799 26966 71 20555 21816 32855 72 3772 27923 33492 73 12837 15856 21575 74 2 16865 34413 75 2682 2702 21630 76 10 22173 34016 77 9740 23216 33800 78 61 33792 33839 79 3961 29314 33446 80 11337 16620 20008 81 18461 25285 34267 82 46 117 8394 83 12291 25671 34505

In another example, when the length N_(ldpc) of the LDPC codeword is 64800, the code rate R is 8/15, and M is 360, the indexes of the rows where 1 is located in the 0^(th) column of the i^(th) column group of the information word submatrix 210 are as shown in Table 19 presented below:

TABLE 19 i Index of row where 1 is located in the 0th column of the ith column group 0 2768 3039 4059 5856 6245 7013 8157 9341 9802 10470 11521 12083 16610 18361 20321 24601 27420 28206 29788 1 2739 8244 8891 9157 12624 12973 15534 16622 16919 18402 18780 19854 20220 20543 22306 25540 27478 27678 28053 2 1727 2268 6246 7815 9010 9556 10134 10472 11389 14599 15719 16204 17342 17666 18850 22058 25579 25860 29207 3 28 1346 3721 5565 7019 9240 12355 13109 14800 16040 16839 17369 17631 19357 19473 19891 20381 23911 29683 4 869 2450 4386 5316 6160 7107 10362 11132 11271 13149 16397 16532 17113 19894 22043 22784 27383 28615 28804 5 508 4292 5831 8559 10044 10412 11283 14810 15888 17243 17538 19903 20528 22090 22652 27235 27384 28208 28485 6 389 2248 5840 6043 7000 9054 11075 11760 12217 12565 13587 15403 19422 19528 21493 25142 27777 28566 28702 7 1015 2002 5764 6777 9346 9629 11039 11153 12690 13068 13990 16841 17702 20021 24106 26300 29332 30081 30196 8 1480 3084 3467 4401 4798 5187 7851 11368 12323 14325 14546 16360 17158 18010 21333 25612 26556 26906 27005 9 6925 8876 12392 14529 15253 15437 19226 19950 20321 23021 23651 24393 24653 26668 27205 28269 28529 29041 29292 10 2547 3404 3538 4666 5126 5468 7695 8799 14732 15072 15881 17410 18971 19609 19717 22150 24941 27908 29018 11 888 1581 2311 5511 7218 9107 10454 12252 13662 15714 15894 17025 18671 24304 25316 25556 28489 28977 29212 12 1047 1494 1718 4645 5030 6811 7868 8146 10611 15767 17682 18391 22614 23021 23763 25478 26491 29088 29757 13 59 1781 1900 3814 4121 8044 8906 9175 11156 14841 15789 16033 16755 17292 18550 19310 22505 29567 29850 14 1952 3057 4399 9476 10171 10769 11335 11569 15002 19501 20621 22642 23452 24360 25109 25290 25828 28505 29122 15 2895 3070 3437 4764 4905 6670 9244 11845 13352 13573 13975 14600 15871 17996 19672 20079 20579 25327 27958 16 612 1528 2004 4244 4599 4926 5843 7684 10122 10443 12267 14368 18413 19058 22985 24257 26202 26596 27899 17 1361 2195 4146 6708 7158 7538 9138 9998 14862 15359 16076 18925 21401 21573 22503 24146 24247 27778 29312 18 5229 6235 7134 7655 9139 13527 15408 16058 16705 18320 19909 20901 22238 22437 23654 25131 27550 28247 29903 19 697 2035 4887 5275 6909 9166 11805 15338 16381 18403 20425 20688 21547 24590 25171 26726 28848 29224 29412 20 5379 17329 22659 23062 21 11814 14759 22329 22936 22 2423 2811 10296 12727 23 8460 15260 16769 17290 24 14191 14608 29536 30187 25 7103 10069 20111 22850 26 4285 15413 26448 29069 27 548 2137 9189 10928 28 4581 7077 23382 23949 29 3942 17248 19486 27922 30 8668 10230 16922 26678 31 6158 9980 13788 28198 32 12422 16076 24206 29887 33 8778 10649 18747 22111 34 21029 22677 27150 28980 35 7918 15423 27672 27803 36 5927 18086 23525 37 3397 15058 30224 38 24016 25880 26268 39 1096 4775 7912 40 3259 17301 20802 41 129 8396 15132 42 17825 28119 28676 43 2343 8382 28840 44 3907 18374 20939 45 1132 1290 8786 46 1481 4710 28846 47 2185 3705 26834 48 5496 15681 21854 49 12697 13407 22178 50 12788 21227 22894 51 629 2854 6232 52 2289 18227 27458 53 7593 21935 23001 54 3836 7081 12282 55 7925 18440 23135 56 497 6342 9717 57 11199 22046 30067 58 12572 28045 28990 59 1240 2023 10933 60 19566 20629 25186 61 6442 13303 28813 62 4765 10572 16180 63 552 19301 24286 64 6782 18480 21383 65 11267 12288 15758 66 771 5652 15531 67 16131 20047 25649 68 13227 23035 24450 69 4839 13467 27488 70 2852 4677 22993 71 2504 28116 29524 72 12518 17374 24267 73 1222 11859 27922 74 9660 17286 18261 75 232 11296 29978 76 9750 11165 16295 77 4894 9505 23622 78 10861 11980 14110 79 2128 15883 22836 80 6274 17243 21989 81 10866 13202 22517 82 11159 16111 21608 83 3719 18787 22100 84 1756 2020 23901 85 20913 29473 30103 86 2729 15091 26976 87 4410 8217 12963 88 5395 24564 28235 89 3859 17909 23051 90 5733 26005 29797 91 1935 3492 29773 92 11903 21380 29914 93 6091 10469 29997 94 2895 8930 15594 95 1827 10028 20070

In another example, when the length N_(ldpc) of the LDPC codeword is 64800, the code rate R is 9/15, and M is 360, the indexes of the rows where 1 is located in the 0^(th) column of the i^(th) column group of the information word submatrix 210 are as shown in Table 20 presented below:

TABLE 20 i Index of row where 1 is located in the 0th column of the ith column group 0 113 1557 3316 5680 6241 10407 13404 13947 14040 14353 15522 15698 16079 17363 19374 19543 20530 22833 24339 1 271 1361 6236 7006 7307 7333 12768 15441 15568 17923 18341 20321 21502 22023 23938 25351 25590 25876 25910 2 73 605 872 4008 6279 7653 10346 10799 12482 12935 13604 15909 16526 19782 20506 22804 23629 24859 25600 3 1445 1690 4304 4851 8919 9176 9252 13783 16076 16675 17274 18806 18882 20819 21958 22451 23869 23999 24177 4 1290 2337 5661 6371 8996 10102 10941 11360 12242 14918 16808 20571 23374 24046 25045 25060 25662 25783 25913 5 28 42 1926 3421 3503 8558 9453 10168 15820 17473 19571 19685 22790 23336 23367 23890 24061 25657 25680 6 0 1709 4041 4932 5968 7123 8430 9564 10596 11026 14761 19484 20762 20858 23803 24016 24795 25853 25863 7 29 1625 6500 6609 16831 18517 18568 18738 19387 20159 20544 21603 21941 24137 24269 24416 24803 25154 25395 8 55 66 871 3700 11426 13221 15001 16367 17601 18380 22796 23488 23938 25476 25635 25678 25807 25857 25872 9 1 19 5958 8548 8860 11489 16845 18450 18469 19496 20190 23173 25262 25566 25668 25679 25858 25888 25915 10 7520 7690 8855 9183 14654 16695 17121 17854 18083 18428 19633 20470 20736 21720 22335 23273 25083 25293 25403 11 48 58 410 1299 3786 10668 18523 18963 20864 22106 22308 23033 23107 23128 23990 24286 24409 24595 25802 12 12 51 3894 6539 8276 10885 11644 12777 13427 14039 15954 17078 19053 20537 22863 24521 25087 25463 25838 13 3509 8748 9581 11509 15884 16230 17583 19264 20900 21001 21310 22547 22756 22959 24768 24814 25594 25626 25880 14 21 29 69 1448 2386 4601 6626 6667 10242 13141 13852 14137 18640 19951 22449 23454 24431 25512 25814 15 18 53 7890 9934 10063 16728 19040 19809 20825 21522 21800 23582 24556 25031 25547 25562 25733 25789 25906 16 4096 4582 5766 5894 6517 10027 12182 13247 15207 17041 18958 20133 20503 22228 24332 24613 25689 25855 25883 17 0 25 819 5539 7076 7536 7695 9532 13668 15051 17683 19665 20253 21996 24136 24890 25758 25784 25807 18 34 40 44 4215 6076 7427 7965 8777 11017 15593 19542 22202 22973 23397 23423 24418 24873 25107 25644 19 1595 6216 22850 25439 20 1562 15172 19517 22362 21 7508 12879 24324 24496 22 6298 15819 16757 18721 23 11173 15175 19966 21195 24 59 13505 16941 23793 25 2267 4830 12023 20587 26 8827 9278 13072 16664 27 14419 17463 23398 25348 28 6112 16534 20423 22698 29 493 8914 21103 24799 30 6896 12761 13206 25873 31 2 1380 12322 21701 32 11600 21306 25753 25790 33 8421 13076 14271 15401 33 8421 13076 14271 15401 34 9630 14112 19017 20955 35 212 13932 21781 25824 36 5961 9110 16654 19636 37 58 5434 9936 12770 38 6575 11433 19798 39 2731 7338 20926 40 14253 18463 25404 41 21791 24805 25869 42 2 11646 15850 43 6075 8586 23819 44 18435 22093 24852 45 2103 2368 11704 46 10925 17402 18232 47 9062 25061 25674 48 18497 20853 23404 49 18606 19364 19551 50 7 1022 25543 51 6744 15481 25868 52 9081 17305 25164 53 8 23701 25883 54 9680 19955 22848 55 56 4564 19121 56 5595 15086 25892 57 3174 17127 23183 58 19397 19817 20275 59 12561 24571 25825 60 7111 9889 25865 61 19104 20189 21851 62 549 9686 25548 63 6586 20325 25906 64 3224 20710 21637 65 641 15215 25754 66 13484 23729 25818 67 2043 7493 24246 68 16860 25230 25768 69 22047 24200 24902 70 9391 18040 19499 71 7855 24336 25069 72 23834 25570 25852 73 1977 8800 25756 74 6671 21772 25859 75 3279 6710 24444 76 24099 25117 25820 77 5553 12306 25915 78 48 11107 23907 79 10832 11974 25773 80 2223 17905 25484 81 16782 17135 20446 82 475 2861 3457 83 16218 22449 24362 84 11716 22200 25897 85 8315 15009 22633 86 13 20480 25852 87 12352 18658 25687 88 3681 14794 23703 89 30 24531 25846 90 4103 22077 24107 91 23837 25622 25812 92 3627 13387 25839 93 908 5367 19388 94 0 6894 25795 95 20322 23546 25181 96 8178 25260 25437 97 2449 13244 22565 98 31 18928 22741 99 1312 5134 14838 100 6085 13937 24220 101 66 14633 25670 102 47 22512 25472 103 8867 24704 25279 104 6742 21623 22745 105 147 9948 24178 106 8522 24261 24307 107 19202 22406 24609

According to an exemplary embodiment, even when the order of numbers, i.e., indexes, in a sequence corresponding to the i^(th) column group of the parity check matrix 200 as shown in the above-described Tables 4 to 20 is changed, the changed parity check matrix is a parity check matrix used for the same LDPC code. Therefore, a case in which the order of numbers in the sequence corresponding to the i^(th) column group in Tables 4 to 20 is changed is covered by the inventive concept.

According to an exemplary embodiment, even when one sequence corresponding to one column group is changed and another sequence corresponding to another column group are changed to each other in Tables 4 to 20, cycle characteristics on a graph of the LDPC code and algebraic characteristics such as degree distribution are not changed. Therefore, a case in which the arrangement order of the sequences shown in Tables 4 to 20 is changed is also covered by the inventive concept.

In addition, even when a multiple of Q_(ldpc) is equally added to all numbers, i.e., indexes, corresponding to a certain column group in Tables 4 to 20, the cycle characteristics on the graph of the LDPC code or the algebraic characteristics such as degree distribution are not changed. Therefore, a result of equally adding a multiple of Q_(ldpc) to the sequences shown in Tables 4 to 20 is also covered by the inventive concept. However, it should be noted that, when the resulting value obtained by adding a multiple of Q_(ldpc) to a given sequence is greater than or equal to (N_(ldpc)−K_(ldpc)), a value obtained by applying a modulo operation for (N_(ldpc)−K_(ldpc)) to the resulting value should be applied instead.

Once positions of the rows where 1 exists in the 0^(th) column of the i^(th) column group of the information word submatrix 210 are defined as shown in Tables 4 to 20, positions of rows where 1 exists in another column of each column group may be defined since the positions of the rows where 1 exists in the 0^(th) column are cyclic-shifted by Q_(ldpc) in the next column.

For example, in the case of Table 4, in the 0^(th) column of the 0^(th) column group of the information word submatrix 210, 1 exists in the 245^(th) row, 449^(th) row, 491^(st) row, . . .

In this case, since Q_(ldpc)=(N_(ldpc)−K_(ldpc))/M=(16200−5400)/360=30, the indexes of the rows where 1 is located in the 1^(st) column of the 0^(th) column group may be 275(=245+30), 479(=449+30), 521(=491+30), . . . , and the indexes of the rows where 1 is located in the 2^(nd) column of the 0^(th) column group may be 305(=275+30), 509(=479+30), 554=521+30).

In the above-described method, the indexes of the rows where 1 is located in all rows of each column group may be defined.

The parity submatrix 220 of the parity check matrix 200 shown in FIG. 2 may be defined as follows:

The parity submatrix 220 includes N_(ldpc)−K_(ldpc) number of columns (that is, K_(ldpc) ^(th) column to (N_(lpdc)−1)^(th) column), and has a dual diagonal or staircase configuration. Accordingly, the degree of columns except the last column (that is, (N_(ldpc)−1)^(th) column) from among the columns included in the parity submatrix 220 is 2, and the degree of the last column is 1.

As a result, the information word submatrix 210 of the parity check matrix 200 may be defined by Tables 4 to 20, and the parity submatrix 220 may have a dual diagonal configuration.

When the columns and rows of the parity check matrix 200 shown in FIG. 2 are permutated based on Equation 4 and Equation 5, the parity check matrix shown in FIG. 2 may be changed to a parity check matrix 300 shown in FIG. 3.

Q _(ldpc) ·i+j⇒M·j+i (0≤i<M,0≤j<Q _(ldpc))   (4)

K _(ldpc) +Q _(ldpc) ·k+l⇒K _(ldpc) +M·l+k (0≤k<M,0≤l<Q _(ldpc))   (5)

The method for permutating based on Equation 4 and Equation 5 will be explained below. Since row permutation and column permutation apply the same principle, the row permutation will be explained by the way of an example.

In the case of the row permutation, regarding the X^(th) row, i and j satisfying X=Q_(ldpc)×i+j are calculated and the X^(th) row is permutated by assigning the calculated i and j to M×j+i. For example, regarding the 7^(th) row, i and j satisfying 7=2×i+j are 3 and 1, respectively. Therefore, the 7^(th) row is permutated to the 13^(th) row (10×1+3=13).

When the row permutation and the column permutation are performed in the above-described method, the parity check matrix of FIG. 2 may be converted into the parity check matrix of FIG. 3.

Referring to FIG. 3, the parity check matrix 300 is divided into a plurality of partial blocks, and a quasi-cyclic matrix of M×M corresponds to each partial block.

Accordingly, the parity check matrix 300 having the configuration of FIG. 3 is formed of matrix units of M×M. That is, the submatrices of M×M are arranged in the plurality of partial blocks, constituting the parity check matrix 300.

Since the parity check matrix 300 is formed of the quasi-cyclic matrices of M×M, M number of columns may be referred to as a column block and M number of rows may be referred to as a row block. Accordingly, the parity check matrix 300 having the configuration of FIG. 3 is formed of N_(qc_column)=N_(ldpc)/M number of column blocks and N_(qc_row)=N_(parity)/M number of row blocks.

Hereinafter, the submatrix of M×M will be explained.

First, the (N_(qc_column)−1)^(th) column block of the 0^(th) row block has a form shown in Equation 6 presented below:

$\begin{matrix} {A = \begin{bmatrix} 0 & 0 & \ldots & 0 & 0 \\ 1 & 0 & \ldots & 0 & 0 \\ 0 & 1 & \ldots & 0 & 0 \\ \vdots & \vdots & \vdots & \vdots & \vdots \\ 0 & 0 & \ldots & 1 & 0 \end{bmatrix}} & (6) \end{matrix}$

As described above, A 330 is an M×M matrix, values of the 0^(th) row and the (M−1)^(th) column are all “0”, and, regarding 0≤i≤(M−2), the (i+1)^(th) row of the i^(th) column is “1” and the other values are “0”.

Second, regarding 0≤i≤(N_(ldpc)−K_(ldpc))/M−1 in the parity submatrix 320, the i^(th) row block of the (K_(ldpc)/M+i)^(th) column block is configured by a unit matrix I_(M×M) 340. In addition, regarding 0≤i≤(N_(ldpc)−K_(ldpc))/M−2, the (i+1)^(th) row block of the (K_(ldpc)/M+i)^(th) column block is configured by a unit matrix I_(M×M) 340.

Third, a block 350 constituting the information word submatrix 310 may have a cyclic-shifted format of a cyclic matrix P, P^(a) ^(ij) , or an added format of the cyclic-shifted matrix P^(a) ^(ij) of the cyclic matrix P (or an overlapping format).

For example, a format in which the cyclic matrix P is cyclic-shifted to the right by 1 may be expressed by Equation 7 presented below:

$\begin{matrix} {P = \begin{bmatrix} 0 & 1 & 0 & \; & 0 \\ 0 & 0 & 1 & \ldots & 0 \\ \vdots & \vdots & \vdots & \; & \vdots \\ 0 & 0 & 0 & \ldots & 1 \\ 1 & 0 & 0 & \; & 0 \end{bmatrix}} & (7) \end{matrix}$

The cyclic matrix P is a square matrix having an M×M size and is a matrix in which a weight of each of M number of rows is 1 and a weight of each of M number of columns is 1. When a_(ij) is 0, the cyclic matrix P, that is, P⁰ indicates a unit matrix I_(M×M), and when a_(ij) is ∞, P^(∞) is a zero matrix.

A submatrix existing where the i^(th) row block and the j^(th) column block intersect in the parity check matrix 300 of FIG. 3 may be P^(a) ^(ij) . Accordingly, i and j indicate the number of row blocks and the number of column blocks in the partial blocks corresponding to the information word. Accordingly, in the parity check matrix 300, the total number of columns is N_(ldpc)=M×N_(qc_column), and the total number of rows is N_(parity)=M×N_(qc_row). That is, the parity check matrix 300 is formed of N_(qc_column) number of column blocks and N_(qc_row) number of row blocks.

Referring back to FIG. 1, the encoder 110 may perform the LDPC encoding by using various code rates such as 5/15, 6/15, 7/15, 8/15, 9/15, 10/15, 11/15, 12/15, 13/15, etc. In addition, the encoder 110 may generate an LDPC codeword having various lengths such as 16200, 64800, etc., based on the length of the information word bits and the code rate.

In this case, the encoder 110 may perform the LDPC encoding by using the parity check matrix, and the parity check matrix is configured as shown in FIGS. 2 and 3.

In addition, the encoder 110 may perform Bose, Chaudhuri, Hocquenghem (BCH) encoding as well as LDPC encoding. To achieve this, the encoder 110 may further include a BCH encoder (not shown) to perform BCH encoding.

In this case, the encoder 110 may perform encoding in an order of BCH encoding and LDPC encoding. Specifically, the encoder 110 may add BCH parity bits to input bits by performing BCH encoding and LDPC-encodes the bits to which the BCH parity bits are added into information word bits, thereby generating the LDPC codeword.

The interleaver 120 interleaves the LDPC codeword. That is, the interleaver 120 receives the LDPC codeword from the encoder 110, and interleaves the LDPC codeword based on various interleaving rules.

In particular, the interleaver 120 may interleave the LDPC codeword such that a bit included in a predetermined group from among a plurality of groups constituting the LDPC codeword (that is, a plurality of bit groups or a plurality of blocks) is mapped onto a predetermined bit of a modulation symbol. Accordingly, the modulator 130 may map a bit included in a predetermined group from among the plurality of groups of the LDPC codeword onto a predetermined bit of the modulation symbol.

Hereinafter, interleaving rules used in the interleaver 120 will be explained in detail according to cases.

Case in Which a Block Interleaver is Used

According to an exemplary embodiment, the interleaver 120 may interleave the LDPC codeword in a method described below such that a bit included in a predetermined group from among a plurality of groups constituting the interleaved LDPC codeword is mapped onto a predetermined bit in a modulation symbol. A detailed description thereof is provided with reference to FIG. 4.

FIG. 4 is a block diagram to illustrate a configuration of an interleaver according to exemplary embodiment. Referring to FIG. 4, the interleaver 120 includes a parity interleaver 121, a group interleaver (or a group-wise interleaver 122), a group twist interleaver 123 and a block interleaver 124.

The parity interleaver 121 interleaves parity bits constituting the LDPC codeword.

Specifically, when the LDPC codeword is generated based on the parity check matrix 200 having the configuration of FIG. 2, the parity interleaver 121 may interleave only the parity bits of the LDPC codeword by using Equations 8 presented below:

u _(i) =c _(i) for 0≤i<K _(ldpc), and

u _(K) _(ldpc) _(+M·t+s) =c _(K) _(ldpc) _(+Q) _(ldpc) _(·s+t) for 0≤s<M, 0≤t<Q _(ldpc)   (8)

where M is an interval at which a pattern of a column group, which includes a plurality of columns, is repeated in the information word submatrix 210, that is, the number of columns included in a column group (for example, M=360), and Q_(ldpc) is a size by which each column is cyclic-shifted in the information word submatrix 210. That is, the parity interleaver 121 performs parity interleaving with respect to the LDPC codeword c=(c₀, c₁, . . . , C_(N) _(ldpc) ⁻¹), and outputs U=(u₀, u₁, . . . , u_(N) _(ldpc) ⁻¹).

When the LDPC codeword encoded based on the parity check matrix 200 of FIG. 2 is parity-interleaved based on Equations 8, the parity-interleaved LDPC codeword is the same as the LDPC codeword encoded by the parity check matrix 300 of FIG. 3. Accordingly, when the LDPC codeword is generated based on the parity check matrix 300 of FIG. 3, the parity interleaver 121 may be omitted.

The LDPC codeword parity-interleaved after having been encoded based on the parity check matrix 200 of FIG. 2, or the LDPC codeword encoded based on the parity check matrix having the format of FIG. 3 may be characterized in that a predetermined number of continuous bits of the LDPC codeword have similar decoding characteristics (cycle distribution, a degree of a column, etc.).

For example, the LDPC codeword may have the same characteristics on the basis of M number of continuous bits. Herein, M is an interval at which a pattern of a column group is repeated in the information word submatrix and, for example, may be 360.

Specifically, a product of the LDPC codeword bits and the parity check matrix should be “0”. This means that a sum of products of the i^(th) LDPC codeword bit, c_(i) (i=0, 1, . . . , N_(ldpc)−1) and the i^(th) column of the parity check matrix should be a “0” vector. Accordingly, the i^(th) LDPC codeword bit may be regarded as corresponding to the i^(th) column of the parity check matrix.

In the case of the parity check matrix of FIG. 2, M number of columns in the information word submatrix 210 belong to the same group and the information word submatrix 210 has the same characteristics on the basis of a column group (for example, the columns belonging to the same column group have the same degree distribution and the same cycle characteristic).

In this case, since M number of continuous bits in the information word bits correspond to the same column group of the information word submatrix 210, the information word bits may be formed of M number of continuous bits having the same codeword characteristics. When the parity bits of the LDPC codeword are interleaved by the parity interleaver 121, the parity bits of the LDPC codeword may be formed of M number of continuous bits having the same codeword characteristics.

In addition, in the case of the parity check matrix 300 of FIG. 3, since the information word submatrix 310 and the parity submatrix 320 of the parity check matrix 300 have the same characteristics on the basis of a column group including M number of columns due to the row and column permutation, the information word bits and the parity bits of the LDPC codeword encoded based on the parity check matrix 300 are formed of M number of continuous bits of the same codeword characteristics.

Herein, the row permutation does not influence the cycle characteristic or algebraic characteristic of the LDPC codeword such as a degree distribution, a minimum distance, etc. since the row permutation is just to rearrange the order of rows in the parity check matrix. In addition, since the column permutation is performed for the parity submatrix 320 to correspond to parity interleaving performed in the parity interleaver 121, the parity bits of the LDPC codeword encoded by the parity check matrix 300 of FIG. 3 are formed of M number of continuous bits like the parity bits of the LDPC codeword encoded by the parity check matrix 200 of FIG. 2.

Accordingly, the bits constituting an LDPC codeword may have the same characteristics on the basis of M number of continuous bits, according to the present exemplary embodiment.

The group interleaver 122 may divide the LDPC codeword into a plurality of groups and rearrange the order of the plurality of groups or may divide the parity-interleaved LDPC codeword into a plurality of groups and rearrange the order of the plurality of groups. That is, the group interleaver 122 interleaves the plurality of groups in group units.

To achieve this, the group interleaver 122 divides the parity-interleaved LDPC codeword into a plurality of groups by using Equation 9 or Equation 10 presented below.

$\begin{matrix} {X_{j} = {{\left\{ {{\left. u_{k} \middle| j \right. = \left\lfloor \frac{k}{360} \right\rfloor},{0 \leq k < N_{ldpc}}} \right\} \mspace{14mu} {for}\mspace{14mu} 0} \leq j < N_{group}}} & (9) \\ {{X_{j} = \left\{ {\left. u_{k} \middle| {{360 \times j} \leq k < {360 \times \left( {j + 1} \right)}} \right.,{0 \leq k < N_{ldpc}}} \right\}}{{{for}\mspace{14mu} 0} \leq j < N_{group}}} & (10) \end{matrix}$

where N_(group) is the total number of groups, X_(j) is the j^(th) group, and u_(k) is the k^(th) LDPC codeword bit input to the group interleaver 122. In addition,

$\left\lfloor \frac{k}{360} \right\rfloor$

is the largest integer below k/360.

Since 360 in these equations indicates an example of the interval M at which the pattern of a column group is repeated in the information word submatrix, 360 in these equations can be changed to M.

The LDPC codeword which is divided into the plurality of groups may be as shown in FIG. 5.

Referring to FIG. 5, the LDPC codeword is divided into the plurality of groups and each group is formed of M number of continuous bits. When M is 360, each of the plurality of groups may be formed of 360 bits.

Specifically, since the LDPC codeword is divided by M number of continuous bits, K_(ldpc) number of information word bits are divided into (K_(ldpc)/M) number of groups and N_(ldpc)−K_(ldpc) number of parity bits are divided into (N_(ldpc)−K_(ldpc))/M number of groups. Accordingly, the LDPC codeword may be divided into (N_(ldpc)/M) number of groups in total. For example, when M=360 and the length N_(ldpc) of the LDPC codeword is 64800, the number of groups N_(groups) is 180, and, when the length N_(ldpc) of the LDPC codeword is 16200, the number of groups N_(group) is 45.

As described above, the group interleaver 122 divides the LDPC codeword such that M number of continuous bits are included in a same group since the LDPC codeword has the same codeword characteristics on the basis of M number of continuous bits. Accordingly, when the LDPC codeword is grouped by M number of continuous bits, the bits having the same codeword characteristics belong to the same group.

In the above-described example, the number of bits constituting each group is M. However, this is merely an example and the number of bits constituting each group is variable.

For example, the number of bits constituting each group may be an aliquot part of M. That is, the number of bits constituting each group may be an aliquot part of the number of columns constituting a column group of the information word submatrix of the parity check matrix. In this case, each group may be formed of aliquot part of M number of bits. For example, when the number of columns constituting a column group of the information word submatrix is 360, that is, M=360, the group interleaver 122 may divide the LDPC codeword into a plurality of groups such that the number of bits constituting each group is one of the aliquot parts of 360.

Hereinafter, the case in which the number of bits constituting a group is M will be explained for convenience of explanation.

Thereafter, the group interleaver 122 interleaves the LDPC codeword in group units. That is, the group interleaver 122 changes positions of the plurality of groups constituting the LDPC codeword and rearranges the order of the plurality of groups constituting the LDPC codeword.

In this case, the group interleaver 122 may rearrange the order of the plurality of groups by using Equation 11 presented below:

Y _(j) =X _(π(j)) (0≤j<N _(group))   (11),

where X_(j) is the j^(th) group before group interleaving, and Y_(j) is the j^(th) group after group interleaving. In addition, π(j) is a parameter indicating an interleaving order and is determined by at least one of a length of an LDPC codeword, a code rate and a modulation method.

Accordingly, X_(π(j)) is a π(j)^(th) group before group interleaving, and Equation 11 means that the pre-interleaving π(j)^(th) group is interleaved into the j^(th) group.

According to an exemplary embodiment, an example of π(j) may be defined as in Tables 21 to 25 presented below.

In this case, π(j) is defined according to a length of an LPDC codeword and a code rate, and a parity check matrix is also defined according to a length of an LDPC codeword and a code rate. Accordingly, when LDPC encoding is performed based on a specific parity check matrix according to a length of an LDPC codeword and a code rate, the LDPC codeword may be interleaved in group units based on π(j) satisfying the corresponding length of the LDPC codeword and code rate.

For example, when the encoder 110 performs LDPC encoding at a code rate of 10/15 to generate an LDPC codeword of a length of 16200, the group interleaver 122 may perform interleaving by using π(j) which is defined according to the length of the LDPC codeword of 16200 and the code rate of 10/15 in tables 21 to 25 presented below.

For example, when the length of the LDPC codeword is 16200, the code rate is 10/15, and the modulation method is 16-Quadrature Amplitude Modulation (QAM), the group interleaver 122 may perform interleaving by using π(j) defined as in table 21.

An example of π(j) is as follows:

For example, when the length N_(ldpc) of the LDPC codeword is 16200, the code rate is 10/15, 11/15, 12/15 and 13/15, and the modulation method is 16-QAM, π(j) may be defined as in Table 21 presented below:

In the case of Table 21, Equation 11 may be expressed as Y₀=X_(π(0))=X₃₅, Y₁=X_(π(1))=X₃₁, Y₂=X_(π(2))=X₃₉, . . . , Y₄₃=X_(π(43))=X₁₅, and Y₄₄=X_(π(44))=X₄₄. Accordingly, the group interleaver 122 may rearrange the order of the plurality of groups by changing the 35^(th) group to the 0^(th) group, the 31^(st) group to the 1^(st) group, the 39^(th) group to the 2^(nd) group, . . . , the 15^(th) group to the 43-^(rd) group, and the 44^(th) group to the 44^(th) group.

In another example, when the length N_(ldpc) of the LDPC codeword is 16200, the code rate is 6/15, 7/15, 8/15 and 9/15, and the modulation method is 16-QAM, π(j) may be defined as in Table 22 presented below:

In the case of Table 22, Equation 11 may be expressed as Y₀=X_(π(0))=X₁₈, Y₁=X_(π(1))=X₃₁, Y₂=X_(π(2))=X₄₁, . . . , Y₄₃=X_(π(43))=X₄₃, and Y₄₄=X_(π(44))=X₄₄. Accordingly, the group interleaver 122 may rearrange the order of the plurality of groups by changing the 18^(th) group to the 0^(th) group, the 31^(st) group to the 1^(st) group, the 41^(st) group to the 2^(nd) group, . . . , the 43^(rd) group to the 43^(rd) group, and the 44^(th) group to the 44^(th) group.

In another example, when the length N_(ldpc) of the LDPC codeword is 16200, the code rate is 10/15, 11/15, 12/15 and 13/15, and the modulation method is 256-QAM, π(j) may be defined as in Table 23 presented below:

In the case of Table 23, Equation 11 may be expressed as Y₀=X_(π(0))=X₄, Y₁=X_(π(1))=X₁₃, Y₂=X_(π(2))=X₃₁, . . . , Y₄₃=X_(π(43))=X₄₃, and Y₄₄=X_(π(44))=X₄₄. Accordingly, the group interleaver 122 may rearrange the order of the plurality of groups by changing the 4^(th) group to the 0^(th) group, the 13^(th) group to the 1^(st) group, the 31^(st) group to the 2^(nd) group, . . . , the 43^(rd) group to the 43^(rd) group, and the 44^(th) group to the 44^(th) group.

In another example, when the length N_(ldpc) of the LDPC codeword is 16200, the code rate is 6/15, 7/15, 8/15 and 9/15, and the modulation method is 1024-QAM, π(j) may be defined as in Table 24 presented below:

In the case of Table 24, Equation 11 may be expressed as Y₀=X_(π(0))=X₁₀, Y₁=X_(π(1))=X₂, Y₂=X_(π(2))=X₂₈, . . . , Y₄₃=X_(π(43))=X₄₃, and Y₄₄=X_(π(44))=X₄₄. Accordingly, the group interleaver 122 may rearrange the order of the plurality of groups by changing the 10^(th) group to the 0th group, the 2^(nd) group to the 1^(st) group, the 28^(th) group to the 2^(nd) group, . . . , the 43^(rd) group to the 43^(rd) group, and the 44^(th) group to the 44^(th) group.

In another example, when the length N_(ldpc) of the LDPC codeword is 64800, the code rate is 6/15, 7/15, 8/15 and 9/15, and the modulation method is 256-QAM, π(j) may be defined as in Table 25 presented below:

In the case of Table 25, Equation 11 may be expressed as Y₀=X_(π(0))=X₉, Y₁=X_(π(1))=X₆, Y₂=X_(π(2))=X₁₆₀, . . . , Y₁₇₈=X_(π(178))=X₁₇₇, and Y₁₇₉=X_(π(179))=X₁₇₆. Accordingly, the group interleaver 122 may rearrange the order of the plurality of groups by changing the 9^(th) group to the 0^(th) group, the 6^(th) group to the 1^(st) group, the 160^(th) group to the 2^(nd) group, . . . , the 177^(th) group to the 178^(th) group, and the 176^(th) group to the 179^(th) group.

As described above, the group interleaver 122 may rearrange the order of the plurality of groups by using Equation 11 and Tables 21 to 25.

On the other hand, since the order of the groups constituting the LDPC codeword is rearranged by the group interleaver 122, and then the groups are block-interleaved by the block interleaver 124, which will be described below, “Order of bits groups to be block interleaved” is set forth in Tables 21 to 25 in relation to π(j).

The LDPC codeword which is group-interleaved in the above-described method is illustrated in FIG. 6. Comparing the LDPC codeword of FIG. 6 and the LDPC codeword of FIG. 5 before group interleaving, it can be seen that the order of the plurality of groups constituting the LDPC codeword is rearranged.

That is, as shown in FIGS. 5 and 6, the groups of the LDPC codeword are arranged in order of group X₀, group X₁, . . . , group X_(Ngroup−1) before being group-interleaved, and are arranged in an order of group Y₀, group Y₁, . . . , group Y_(Ngroup−1) after being group-interleaved. In this case, the order of arranging the groups by the group interleaving may be determined based on Tables 21 to 25.

The group twist interleaver 123 interleaves bits in a same group. That is, the group twist interleaver 123 may rearrange the order of the bits in the same group by changing the order of the bits in the same group.

In this case, the group twist interleaver 123 may rearrange the order of the bits in the same group by cyclic-shifting a predetermined number of bits from among the bits in the same group.

For example, as shown in FIG. 7, the group twist interleaver 123 may cyclic-shift bits included in the group Y₁ to the right by 1 bit. In this case, the bits located in the 0^(th) position, the 1^(st) position, the 2^(nd) position, . . . , the 358^(th) position, and the 359^(th) position in the group Y₁ as shown in FIG. 7 are cyclic-shifted to the right by 1 bit. As a result, the bit located in the 359^(th) position before being cyclic-shifted is located in the front of the group Y₁ and the bits located in the 0^(th) position, the 1^(st) position, the 2^(nd) position, . . . , the 358^(th) position before being cyclic-shifted are shifted to the right serially by 1 bit and located.

In addition, the group twist interleaver 123 may rearrange the order of bits in each group by cyclic-shifting a different number of bits in each group.

For example, the group twist interleaver 123 may cyclic-shift the bits included in the group Y₁ to the right by 1 bit, and may cyclic-shift the bits included in the group Y₂ to the right by 3 bits.

However, the above-described group twist interleaver 123 may be omitted according to circumstances.

In addition, the group twist interleaver 123 is placed after the group interleaver 122 in the above-described example. However, this is merely an example. That is, the group twist interleaver 123 changes only the order of bits in a certain group and does not change the order of the groups. Therefore, the group twist interleaver 123 may be placed before the group interleaver 122.

The block interleaver 124 interleaves the plurality of groups the order of which has been rearranged. Specifically, the block interleaver 124 may interleave the plurality of groups the order of which has been rearranged by the group interleaver 122.

Herein, the number of groups which are interleaved in group units may be determined by at least one of the number of rows and columns constituting the block interleaver 124, the number of groups and the number of bits included in each group. In other words, the block interleaver 124 may determine the groups which are to be interleaved in group units considering at least one of the number of rows and columns constituting the block interleaver 124, the number of groups and the number of bits included in each group, interleave the corresponding groups in group units, and divide and interleave the remaining groups.

Meanwhile, interleaving groups in group units means that the bits included in the same group are written in the same column. In other words, the block interleaver 124 may not divide the bits included in the groups which are interleaved in group units and write the bits in the same column, and may divide the bits in the groups which are not interleaved in group units and write the bits in different columns.

The specific interleaving method will be described later.

In this case, the group twist interleaver 123 changes only the order of bits in the same group and does not change the order of groups by interleaving. Accordingly, the order of the groups to be block-interleaved by the block interleaver 124, that is, the order of the groups to be input to the block interleaver 124, may be determined by the group interleaver 122. Specifically, the order of the groups to be block-interleaved by the block interleaver 124 may be determined by π(j) defined in Tables 21 to 25.

The block interleaver 124 may be formed of a plurality of columns each including a plurality of rows, and may divide the plurality of columns into at least two parts and interleave an LDPC codeword.

In this case, the block interleaver 124 may divide each of the plurality of columns into N number of parts (N is an integer greater than or equal to 2) according to whether the number of groups constituting the LDPC codeword is an integer multiple of the number of columns constituting the block interleaver 124, and may perform interleaving.

When the number of groups constituting the LDPC codeword is an integer multiple of the number of columns constituting the block interleaver 124, the block interleaver 124 may interleave the plurality of groups constituting the LDPC codeword in group units without dividing each of the plurality of columns into parts.

Specifically, the block interleaver 124 may interleave by writing the plurality of groups of the LDPC codeword on each of the columns in group units in a column direction, and reading each row of the plurality of columns in which the plurality of groups are written in group units in a row direction.

In this case, the block interleaver 124 may interleave by writing bits included in a predetermined number of groups which corresponds to the number of groups of the LDPC codeword divided by the number of columns of the block interleaver 124 on each of the plurality of columns serially in a column direction, and reading each row of the plurality of columns in which the bits are written in a row direction.

Hereinafter, the group located in the j^(th) position after being interleaved by the group interleaver 122 will be referred to as group Y_(j).

For example, it is assumed that the block interleaver 124 is formed of C number of columns each including R₁ number of rows. In addition, it is assumed that the LDPC codeword is formed of Y_(group) number of groups and the number of groups Y_(group) is a multiple of C.

In this case, the block interleaver 124 may interleave by writing Y_(group)/C number of groups on each column serially in a column direction and reading bits written on each column in a row direction.

For example, as shown in FIG. 8, the block interleaver 124 writes bits included in group Y₀, group Y₁, . . . , group Y_(p−1) in the 1^(st) column from the 1^(st) row to the R₁ ^(th) row, writes bits included in group Y_(p), group Y_(p+1), . . . , group Y_(q−1) in the 2nd column from the 1^(st) row to the R₁ ^(th) row, . . . , and writes bits included in group Y_(z), Y_(z+1), . . . , group Y_(Ngroup−1) in the column C from the 1^(st) row to the R₁ ^(th) row. The block interleaver 124 may read the bits written in each row of the plurality of columns in a row direction.

Accordingly, the block interleaver 124 interleaves all groups constituting the LDPC codeword in group units.

However, when the number of groups of the LDPC codeword is not an integer multiple of the number of columns of the block interleaver 124, the block interleaver 124 may interleave a part of the plurality of groups of the LDPC codeword in group units by dividing each column into 2 parts. In this case, the remaining groups are not interleaved in group units, but interleaved by being divided according to the number of columns.

That is, the block interleaver 124 may interleave the LDPC codeword by dividing each of the plurality of columns into two parts.

In this case, the block interleaver 124 may divide the plurality of columns into a first part (part 1) and a second part (part 2) based on the number of columns of the block interleaver 124 and the number of bits of each of the plurality of groups.

Here, each of the plurality of groups may be formed of 360 bits. In addition, the number of columns constituting the block interleaver 124 may be determined according to a modulation method. This will be explained in detail below.

That is, the number of rows constituting each of the first part and the second part may be determined based on the number of columns constituting the block interleaver 124 and the number of bits constituting each of the plurality of groups.

Specifically, in each of the plurality of columns, the first part may be formed of as many rows as the number of bits included in at least one group which can be written in each column in group units from among the plurality of groups of the LDPC codeword, according to the number of columns constituting the block interleaver 124 and the number of bits constituting each of the plurality of groups. In each of the plurality of columns, the second part may be formed of rows excluding as many rows as the number of bits included in at least some groups which can be written in each of the plurality of columns in group units.

That is, the block interleaver 124 may divide each of the plurality of columns into the first part including as many rows as the number of bits included in groups which can be written in each column in group units, and the second part including the other rows.

Accordingly, the first part may be formed of as many rows as the number of bits included in groups, that is, as many rows as an integer multiple of M. However, since the number of codeword bits constituting each group may be an aliquot part of M as described above, the first part may be formed of as many rows as an integer multiple of the number of bits constituting each group.

In this case, the block interleaver 124 may interleave by writing and reading the LDPC codeword in the first part and the second part in the same method.

Specifically, the block interleaver 124 may interleave by writing the LDPC codeword in the plurality of columns constituting each of the first part and the second part in a column direction, and reading the plurality of columns consisting the first part and the second part in which the LDPC codeword is written in a row direction.

That is, the block interleaver may interleave by writing at least some groups which can be written in each of the plurality of columns in group units in each of the plurality of columns of the first part in a column direction, dividing the other groups except the at least some groups and writing in each of the plurality of columns of the second part in a column direction, and reading the bits written in each of the plurality of columns constituting each of the first part and the second part in a row direction.

In this case, the block interleaver 124 may divide the other groups except the at least some groups from among the plurality of groups based on the number of columns constituting the block interleaver 124. That is, the block interleaver 124 may divide the bits included in the other groups except the groups written in the first part from among the plurality of groups of the LDPC codeword by the number of columns, and may write the divided bits in each column of the second part serially in a column direction.

For example, it is assumed that the block interleaver 124 is formed of C number of columns each including R₁ number of rows. In addition, it is assumed that the LDPC codeword is formed of Y_(group) number of groups, the number of groups Y_(group) is not a multiple of C, and A×C+1=Y_(group) (A is an integer greater than 0).

In this case, as shown in FIGS. 9 and 10, the block interleaver 124 may divide each column into a first part including R₁ number of rows and a second part including R₂ number of rows. In this case, R₁ may correspond to the number of bits included in groups which can be written in each column in group units, and R₂ may be R₁ subtracted from the number of rows of each column.

That is, in the above-described example, the number of groups which can be written in each column in group units is A, and the first part of each column may be formed of as many rows as the number of bits included in A number of groups, that is, may be formed of as many rows as A×M number.

In this case, the block interleaver 124 writes the bits included in the groups which can be written in each column in group units, that is, A number of groups, in the first part of each column in the column direction.

That is, as shown in FIGS. 9 and 10, the block interleaver 124 writes the bits included in each of group Y₀, group Y₁, . . . , group Y_(n−)in the 1^(st) to R₁ ^(th) rows of the first part of the 1^(st) column, writes bits included in each of group Y_(n), group Y_(n+1), . . . , group Y_(m−1) in the 1^(st) to R₁ ^(th) rows of the first part of the 2^(nd) column, . . . , writes bits included in each of group Y_(e), group Y_(e+1), . . . , group Y_(Ngroup−2) in the 1^(st) to R₁ ^(th) rows of the first part of the column C.

As described above, the block interleaver 124 writes the bits included in the groups which can be written in each column in group units in the first part of each column in in group units.

Thereafter, the block interleaver 124 divides bits included in the other groups except the groups written in the first part of each column from among the plurality of groups, and writes the bits in the second part of each column in the column direction. In this case, the block interleaver 124 divides the bits included in the other groups except the groups written in the first part of each column by the number of columns, so that the same number of bits are written in the second part of each column, and writes the divided bits in the second part of each column in the column direction.

In the above-described example, since A×C+1=Y_(group), the last group Y_(Ngroup−1) of the LDPC codeword is not written in the first part and remains. Accordingly, the block interleaver 124 divides the bits included in the group Y_(Ngroup−1) by C as shown in FIG. 9, and writes the divided bits in the second part of each column serially.

That is, the block interleaver 124 writes the bits in the 1^(st) to R₂ ^(th) rows of the second part of the 1^(st) column, writes the bits in the 1^(st) to R₂ ^(th) rows of the second part of the 2^(nd) column, . . . , etc., and writes the bits in the 1^(st) to R₂ ^(th) rows of the second part of the column C. In this case, the block interleaver 124 may write the bits in the second part of each column in the column direction as shown in FIG. 9. That is, in the second part, the bits constituting the bit group may not be written in the same column and may be written in the plurality of columns.

In the above-described example, the block interleaver 124 writes the bits in the second part in the column direction. However, this is merely an example. That is, the block interleaver 124 may write the bits in the plurality of columns of the second parts in a row direction. In this case, the block interleaver 124 may write the bits in the first part in the same method as described above.

Specifically, referring to FIG. 10, the block interleaver 124 writes the bits from the 1^(st) row of the second part in the 1^(st) column to the 1^(st) row of the second part in the column C, writes the bits from the 2^(nd) row of the second part in the 1^(st) column to the 2^(nd) row of the second part in the column C, . . . , etc., and writes the bits from the R₂ ^(th) row of the second part in the 1^(st) column to the R₂ ^(th) row of the second part in the column C.

On the other hand, the block interleaver 124 reads the bits written in each row of each part serially in the row direction. That is, as shown in FIGS. 9 and 10, the block interleaver 124 reads the bits written in each row of the first part of the plurality of columns serially in the row direction, and reads the bits written in each row of the second part of the plurality of columns serially in the row direction.

Accordingly, the block interleaver 124 may interleave a part of a plurality of groups constituting the LDPC codeword in group units, and divide and interleave the remaining groups.

As described above, the block interleaver 124 may interleave the plurality of groups in the methods described above with reference to FIGS. 8 to 10.

In particular, in the case of FIG. 9, the bits included in the group which does not belong to the first part are written in the second part in the column direction and read in the row direction. In view of this, the order of the bits included in the group which does not belong to the first part is rearranged. Since the bits included in the group which does not belong to the first part are interleaved as described above, Bit Error Rate (BER)/Frame Error Rate (FER) performance can be improved in comparison with a case in which such bits are not interleaved.

However, the group which does not belong to the first part may not be interleaved as shown in FIG. 10. That is, since the block interleaver 124 writes and read the bits included in the group which does not belong to the first part on and from the second part in the row direction, the order of the bits included in the group which does not belong to the first part is not changed and the bits are output to the modulator 130 serially. In this case, the bits included in the group which does not belong to the first part may be output serially and mapped onto a modulation symbol.

In FIGS. 9 and 10, the last single group of the plurality of groups is written in the second part. However, this is merely an example. The number of groups written in the second part may vary according to the total number of groups of the LDPC codeword, the number of columns and rows, the number of transmission antennas, etc.

The block interleaver 124 may have a different configuration according to whether bits included in a same group are mapped onto a single bit of each modulation symbol or bits included in a same group are mapped onto two bits of each modulation symbol.

On the other hand, in the case of a transceiving system using a plurality of antennas, the number of columns constituting the block interleaver 124 may be determined by considering the number of bits constituting a modulation symbol and the number of used antennas simultaneously. For example, when bits included in a same group are mapped onto a single bit in a modulation symbol and two antennas are used, the block interleaver 124 may determine the number of columns to be two times the number of bits constituting the modulation symbol.

First, when bits included in the same group are mapped onto a single bit of each modulation symbol, the block interleaver 124 may have configurations as shown in Tables 26 and 27:

TABLE 26 N_(ldpc) = 64800 16 64 256 1024 4096 QPSK QAM QAM QAM QAM QAM C 2 4 6 8 10 12 R₁ 32400 16200 10800 7920 6480 5400 R₂ 0 0 0 180 0 0

TABLE 27 N_(ldpc) = 16200 16 64 256 1024 4096 QPSK QAM QAM QAM QAM QAM C 2 4 6 8 10 12 R₁ 7920 3960 2520 1800 1440 1080 R₂ 180 90 180 225 180 270

Herein, C (or N_(C)) is the number of columns of the block interleaver 124, R₁ is the number of rows constituting the first part in each column, and R₂ is the number of rows constituting the second part in each column.

Referring to Tables 26 and 27, when the number of groups constituting an LDPC codeword is an integer multiple of the number of columns, the block interleaver 124 interleaves without dividing each column. Therefore, R₁ corresponds to the number of rows constituting each column, and R₂ is 0. In addition, when the number of groups constituting an LDPC codeword is not an integer multiple of the number of columns, the block interleaver 124 interleaves the groups by dividing each column into the first part formed of R₁ number of rows, and the second part formed of R₂ number of rows.

When the number of columns of the block interleaver 124 is equal to the number of bits constituting a modulation symbol, bits included in a same group are mapped onto a single bit of each modulation symbol as shown in Tables 26 and 27.

For example, when N_(ldpc)=64800 and the modulation method is 16-QAM, the block interleaver 124 may use four (4) columns each including 16200 rows. In this case, a plurality of groups of an LDPC codeword are written in the four (4) columns in group units and bits written in the same row in each column are output serially. In this case, since four (4) bits constitute a single modulation symbol in the modulation method of 16-QAM, bits included in the same group, that is, bits output from a single column, may be mapped onto a single bit of each modulation symbol. For example, bits included in a group written in the 1st column may be mapped onto the first bit of each modulation symbol.

On the other hand, when bits included in a same group are mapped onto two bits of each modulation symbol, the block interleaver 124 may have configurations as shown in Tables 28 and 29:

TABLE 28 N_(ldpc) = 64800 16 64 1024 4096 QPSK QAM QAM 256QAM QAM QAM C 1 2 3 4 5 6 R₁ 64800 32400 21600 16200 12960 10800 R₂ 0 0 0 0 0 0

TABLE 29 N_(ldpc) = 16200 16 64 256 1024 4096 QPSK QAM QAM QAM QAM QAM C 1 2 3 4 5 6 R₁ 16200 7920 5400 3960 3240 2520 R₂ 0 180 0 90 0 180

Herein, C (or N_(C)) is the number of columns of the block interleaver 124, R₁ is the number of rows constituting the first part in each column, and R₂ is the number of rows constituting the second part in each column.

Referring to Tables 28 and 29, when the number of groups constituting an LDPC codeword is an integer multiple of the number of columns, the block interleaver 124 interleaves without dividing each column. Therefore, R₁ corresponds to the number of rows constituting each column, and R₂ is 0. In addition, when the number of groups constituting an LDPC codeword is not an integer multiple of the number of columns, the block interleaver 124 interleaves the groups by dividing each column into the first part formed of R₁ number of rows, and the second part formed of R₂ number of rows.

When the number of columns of the block interleaver 124 is half of the number of bits constituting a modulation symbol as shown in Tables 28 and 29, bits included in a same group are mapped onto two bits of each modulation symbol.

For example, when N_(ldpc)=64800 and the modulation method is 16-QAM, the block interleaver 124 may use two (2) columns each including 32400 rows. In this case, a plurality of groups of an LDPC codeword are written in the two (2) columns in group units and bits written in the same row in each column are output serially. Since four (4) bits constitute a single modulation symbol in the modulation method of 16-QAM, bits output from two rows constitute a single modulation symbol. Accordingly, bits included in the same group, that is, bits output from a single column, may be mapped onto two bits of each modulation symbol. For example, bits included in a group written in the 1^(st) column may be mapped onto bits existing in any two positions of each modulation symbol.

Referring to Tables 26 to 29, the total number of rows of the block interleaver 124, that is, R₁+R₂, is N_(ldpc)/C.

In addition, the number of rows of the first part, R₁, is an integer multiple of the number of bits included in each group, M (e.g., M=360), and may be expressed as └N_(group)/C┘×M, and the number of rows of the second part, R₂, may be N_(ldpc)/C−R₁. Herein, └N_(group)/C┘ is the largest integer below N_(ldpc)/C. Since R₁ is an integer multiple of the number of bits included in each group, M, bits may be written in R₁ in group units.

In addition, when the number of groups of an LDPC codeword is not a multiple of the number of columns, it can be seen from Tables 26 to 29 that the block interleaver 124 interleaves a plurality of groups of the LDPC codeword by dividing each column into two parts.

Specifically, the length of an LDPC codeword divided by the number of columns is the total number of rows included in the each column. In this case, when the number of groups of the LDPC codeword is a multiple of the number of columns, each column is not divided into two parts. However, when the number of groups of the LDPC codeword is not a multiple of the number of columns, each column is divided into two parts.

For example, it is assumed that the number of columns of the block interleaver 124 is identical to the number of bits constituting a modulation symbol, and an LDPC codeword is formed of 64800 bits as shown in Table 26. In this case, each group of the LDPC codeword is formed of 360 bits, and the LDPC codeword is formed of 64800/360(=180) groups.

When the modulation method is 16-QAM, the block interleaver 124 may use four (4) columns and each column may have 64800/4(=16200) rows.

In this case, since the number of groups of an LDPC codeword divided by the number of columns is 180/4(=45), bits can be written in each column in group units without dividing each column into two parts. That is, bits included in 45 groups, that is, 45×360(=16200) bits can be written in each column.

However, when the modulation method is 256-QAM, the block interleaver 124 may use eight (8) columns and each column may have 64800/8(=8100) rows.

In this case, since the number of groups of an LDPC codeword divided by the number of columns is 180/8=22.5, the number of groups constituting the LDPC codeword is not an integer multiple of the number of columns. Accordingly, the block interleaver 124 divides each of the eight (8) columns into two parts to perform interleaving in group units.

In this case, since the bits should be written in the first part of each column in group units, the number of groups which can be written in the first part of each column in group units is 22, and accordingly, the first part of each column has 22×360(=7920) rows. Accordingly, 7920 bits included in 22 groups may be written in the first part of each column.

The second part of each column has rows which are the rows of the first part subtracted from the total rows of each column. Accordingly, the second part of each column includes 8100−7920(=180) rows.

In this case, the bits included in the other group which has not been written in the first part are divided and written in the second part of each column.

Specifically, since 22×8(=176) groups are written in the first part, the number of groups to be written in the second part is 180−176 (=4) (for example, group Y₁₇₆, group Y₁₇₇, group Y₁₇₈, and group Y₁₇₉ from among group Y₀, group Y₁, group Y₂, . . . , group Y₁₇₈, and group Y₁₇₉ constituting an LDPC codeword).

Accordingly, the block interleaver 124 may write the four (4) groups which have not been written in the first part and remains from among the groups constituting the LDPC codeword in the second part of each column serially.

That is, the block interleaver 124 may write 180 bits of the 360 bits included in the group Y₁₇₆ in the 1^(st) row to the 180^(th) row of the second part of the 1^(st) column in the column direction, and may write the other 180 bits in the 1^(st) row to the 180^(th) row of the second part of the 2^(nd) column in the column direction. In addition, the block interleaver 124 may write 180 bits of the 360 bits included in the group Y₁₇₇ in the 1^(st) row to the 180^(th) row of the second part of the 3^(rd) column in the column direction, and may write the other 180 bits in the 1^(st) row to the 180^(th) row of the second part of the 4^(th) column in the column direction. In addition, the block interleaver 124 may write 180 bits of the 360 bits included in the group Y₁₇₈ in the 1^(st) row to the 180^(th) row of the second part of the 5^(th) column in the column direction, and may write the other 180 bits in the 1^(st) row to the 180^(th) row of the second part of the 6^(th) column in the column direction. In addition, the block interleaver 124 may write 180 bits of the 360 bits included in the group Y₁₇₉ in the 1^(st) row to the 180^(th) row of the second part of the 7^(th) column in the column direction, and may write the other 180 bits in the 1^(st) row to the 180^(th) row of the second part of the 8^(th) column in the column direction.

Accordingly, the bits included in the group which has not been written in the first part and remains are not written in the same column in the second part and may be divided and written in the plurality of columns.

Hereinafter, the block interleaver of FIG. 4 according to an exemplary embodiment will be explained in detail with reference to FIG. 11.

In a group-interleaved LDPC codeword (v₀, v₁, . . . , v_(N) _(ldpc) ⁻¹), Y_(j) is continuously arranged like V={Y₀, Y₁, . . . Y_(N) _(group) ⁻¹}.

The LDPC codeword after group interleaving may be interleaved by the block interleaver 124 as shown in FIG. 11. Specifically, an input bit v_(i) is written from the first part to the second part serially in a column direction, and is read from the first part to the second part serially in a row direction.

In this case, the number of columns and the number of rows of the first part and the second part of the block interleaver 124 vary according to a modulation method as in Table 51 presented below.

Herein, a sum of the number of rows of the first part, N_(r1) and the number of rows of the second part, N_(r2), is equal to N_(ldpc)/N_(C) (herein, N_(C) is the number of columns). In addition, since N_(r1) is a multiple of 360, a plurality of bit groups may be written in the first part.

TABLE 30 Rows in Part 1 N_(r1) Rows in Part 2 N_(r2) Columns Modulation N_(ldpc) = 64800 N_(ldpc) = 16200 N_(ldpc) = 64800 N_(ldpc) = 16200 N_(c)  16-QAM 16200 3960 0 90 4  64-QAM 10800 2520 0 180 6  256-QAM 7920 1800 180 225 8 1024-QAM 6480 1440 0 180 10

Hereinafter, an operation of the block interleaver 124 will be explained in detail.

Specifically, as shown in FIG. 11, the input bit v_(i) (0≤i<N_(C)×N_(r1)) is written in r₁row of c_(i) column of the first part of the block interleaver 124. Herein, c_(i) and r_(i) are

$c_{i}\left\lfloor \frac{i}{N_{r\; 1}} \right\rfloor$

and r_(i)=(i mod N_(r1)), respectively.

In addition, the input bit v_(i) (N_(C)×N_(r1)≤i<N_(ldpc)) is written in an r_(i) row of c_(i) column of the second part of the block interleaver 124. Herein, c_(i) and r_(i) are

$c_{i}\left\lfloor \frac{\left( {i - {N_{C} \times N_{r\; 1}}} \right)}{N_{r\; 2}} \right\rfloor$

and r_(i)=N_(r1)+{(i−N_(C)×N_(r1))mod N_(r2)}, respectively.

An output bit q_(j) (0≤j<N_(ldpc)) is read from c_(j) column of r_(j) row. Herein, r_(j) and c_(j) are

$r_{j}\left\lfloor \frac{j}{N_{c}} \right\rfloor$

and c_(j)=(j mod N_(C)), respectively.

For example, when the length N_(ldpc) of an LDPC codeword is 64800 and the modulation method is 256-QAM, an order of bits output from the block interleaver 124 may be (q₀,q₁,q₂, . . . ,q₆₃₃₅₇,q₆₃₃₅₈,q₆₃₃₅₉,q₆₃₃₆₀,q₆₃₃₆₁, . . . ,q₆₄₇₉₉)=(v₀,v₇₉₂₀,v₁₅₈₄₀, . . . ,v₄₇₅₁₉,v₅₅₄₃₉,v₆₃₃₅₉,v₆₃₃₆₀,v₆₃₅₄₀, . . . ,v₆₄₇₉₉). Herein, the indexes of the right side of the foregoing equation may be specifically expressed for the eight (8) columns as 0, 7920, 15840, 23760, 31680, 39600, 47520, 55440, 1, 7921, 15841, 23761, 31681, 39601, 47521, 55441, . . . , 7919, 15839, 23759, 31679, 39599, 47519, 55439, 63359, 63360, 63540, 63720, 63900, 64080, 64260, 64440, 64620, . . . , 63539, 63719, 63899, 64079, 64259, 64439, 64619, 64799.

Referring back to FIG. 1, the modulator 130 modulates an interleaved LDPC codeword according to a modulation method to generate a modulation symbol. Specifically, the modulator 130 may demultiplex the interleaved LDPC codeword and modulate the demultiplexed LDPC codeword and map it onto a constellation, thereby generating a modulation symbol.

In this case, the modulator 130 may generate a modulation symbol using bits included in each of a plurality of groups.

In other words, as described above, the bits included in different groups are written in each column of the block interleaver 124, and the block interleaver 124 reads the bits written in each column in a row direction. In this case, the modulator 130 generates a modulation symbol by mapping the bits read in each column onto each bit of the modulation symbol. Accordingly, each bit of the modulation symbol belongs to a different group.

For example, it is assumed that the modulation symbol consists of C bits (C refers to the number of bits). In this case, the bits which are read from each row of C columns of the block interleaver 124 may be mapped onto each bit of the modulation symbol and thus, each bit of the modulation symbol consisting of C bits belong to C different groups.

Hereinbelow, the above feature will be described in greater detail.

First, the modulator 130 demultiplexes the interleaved LDPC codeword. To achieve this, the modulator 130 may include a demultiplexer (not shown) to demultiplex the interleaved LDPC codeword.

The demultiplexer (not shown) demultiplexes the interleaved LDPC codeword. Specifically, the demultiplexer (not shown) performs serial-to-parallel conversion with respect to the interleaved LDPC codeword, and demultiplexes the interleaved LDPC codeword into a cell having a predetermined number of bits (or a data cell).

For example, as shown in FIG. 12, the demultiplexer (not shown) receives the LDPC codeword Q=(q₀, q₁, q₂, . . . ) output from the interleaver 120, outputs the received LDPC codeword bits to one of a plurality of substreams serially, converts the input LDPC codeword bits into cells, and outputs the cells.

Herein, the number of substreams, N_(substreams), may be equal to the number of bits constituting a modulation symbol, η_(mod), and the number of bits constituting the cell may be equal to N_(ldpc)/η_(mod). η_(mod) varying according to a modulation method and the number of cells generated according to the length N_(ldpc) of the LDPC codeword are as in Table 31 presented below:

TABLE 31 Number of output Number of output data cells for N_(ldpc) = data cells for N_(ldpc) = Modulation mode η_(MOD) 64 800 16 200 QPSK 2 32 400 8 100  16-QAM 4 16 200 4 050  64-QAM 6 10 800 2 700  256-QAM 8  8 100 2 025 1024-QAM 10  6 480 1 620

Bits having the same index in each of the plurality of sub-streams may constitute a same cell. That is, in FIG. 12, each cell may be expressed as (y_(0,0), y_(1,0), . . . , y_(ηMOD−1,0)), (y_(0,1), y_(1,1), . . . , y_(ηMOD−1,1)).

The demultiplexer (not shown) may demultiplex input LDPC codeword bits in various methods. That is, the demultiplexer (not shown) may change an order of the LDPC codeword bits and output the bits to each of the plurality of substreams, or may output the bits to each of the plurality of streams serially without changing the order of the LDPC codeword bits. These operations may be determined according to the number of columns used for interleaving in the block interleaver 124.

Specifically, when the block interleaver 124 includes as many columns as half of the number of bits constituting a modulation symbol, the demultiplexer (not shown) may change the order of the input LDPC codeword bits and output the bits to each of the plurality of sub-streams. An example of a method for changing the order is illustrated in Table 32 presented below:

According to Table 32, when the modulation method is 16-QAM for example, the number of substreams is four (4) since the number of bits constituting the modulation symbol is four (4) in the case of 16-QAM. In this case, the demultiplexer (not shown) may output, from among the serially input bits, bits with an index i satisfying i mod 4=0 to the 0^(th) substream, bits with an index i satisfying i mod 4=1 to the 2^(nd) substream, bits with an index i satisfying i mode 4=2 to the 1^(st) substream, and bits with an index i satisfying i mode 4=3 to the 3^(rd) substream.

Accordingly, the LDPC codeword bits input to the demultiplexer (not shown), (q₀, q₁, q₂, . . . ), may be output as cells like (y_(0,0), y_(1,0), y_(2,0), y_(3,0))=(q₀, q₂, q₁, q₃), (y_(0,1), y_(1,1), y_(2,1), y_(3,1))=(q₄, q₆, q₅, q₇), . . .

When the block interleaver 124 includes the same number of columns as the number of bits constituting a modulation symbol, the demultiplexer (not shown) may output the input LDPC codeword bits to each of the plurality of streams serially without changing the order of the bits. That is, as shown in FIG. 13, the demultiplexer (not shown) may output the input LDPC codeword bits (q₀, q₁, q₂, . . . ) to each of the substreams serially, and accordingly, each cell may be configured as (y_(0,0),y_(1,0), . . . ,y_(ηMOD−1,0))=(q₀,q₁, . . . ,q_(ηMOD−1)), (y_(0,1),y_(1,1), . . . ,y_(ηMOD−)1,1)=(q_(ηMOD),q_(ηMOD+1), . . . ,q_(ηMOD−1)), . . .

In the above-described example, the demultiplexer (not shown) outputs the input LDPC codeword bits to each of the plurality of streams serially without changing the order of the bits. However, this is merely an example. That is, according to an exemplary embodiment, when the block interleaver 124 includes the same number of columns as the number of bits constituting a modulation symbol, the demultiplexer (not shown) may be omitted.

The modulator 130 may map the demultiplexed LDPC codeword onto modulation symbols. However, when the demultiplexer (not shown) is omitted as described above, the modulator 130 may map LDPC codeword bits output from the interleaver 120, that is, block-interleaved LDPC codeword bits, onto modulation symbols.

The modulator 130 may modulate bits (that is, cells) output from the demultiplexer (not shown) in various modulation methods such as QPSK, 16-QAM, 64-QAM, 256-QAM, 1024-QAM, 4096-QAM, etc. When the modulation method is QPSK, 16-QAM, 64-QAM, 256-QAM, 1024-QAM and 4096-QAM, the number of bits constituting a modulation symbol, η_(MOD) (that is, a modulation degree), may be 2, 4, 6, 8, 10 and 12, respectively.

In this case, since each cell output from the demultiplexer (not shown) is formed of as many bits as the number of bits constituting a modulation symbol, the modulator 130 may generate a modulation symbol by mapping each cell output from the demultiplexer (not shown) onto a constellation point serially. Herein, a modulation symbol corresponds to a constellation point on the constellation.

However, when the demultiplexer (not shown) is omitted, the modulator 130 may generate modulation symbols by grouping a predetermined number of bits from interleaved bits sequentially and mapping the predetermined number of bits onto constellation points. In this case, the modulator 130 may generate the modulation symbols by using η_(MOD) number of bits sequentially according to a modulation method.

The modulator 130 may modulate by mapping cells output from the demultiplexer (not shown) onto constellation points in a uniform constellation (UC) method.

The uniform constellation method refers to a method for mapping a modulation symbol onto a constellation point so that a real number component Re(z_(q)) and an imaginary number component Im(z_(q)) of a constellation point have symmetry and the modulation symbol is placed at equal intervals. Accordingly, at least two of modulation symbols mapped onto constellation points in the uniform constellation method may have the same demodulation performance.

Examples of the method for generating a modulation symbol in the uniform constellation method according to an exemplary embodiment are illustrated in Tables 33 to 40 presented below, and an example of a case of a uniform constellation 64-QAM is illustrated in FIG. 14.

TABLE 33 y_(0,q) 1 0 Re(z_(q)) −1 1

TABLE 34 Y_(1,q) 1 0 Im(z_(q)) −1 1

TABLE 35 y_(0,q) 1 1 0 0 y_(2,q) 0 1 1 0 Re(z_(q)) −3 −1 1 3

TABLE 36 y_(1,q) 1 1 0 0 y_(3,q) 0 1 1 0 Im(z_(q)) −3 −1 1 3

TABLE 37 y_(0, q) 1 1 1 1 0 0 0 0 y_(2, q) 0 0 1 1 1 1 0 0 y_(4, q) 0 1 1 0 0 1 1 0 Re(z_(q)) −7 −5 −3 −1 1 3 5 7

TABLE 38 y_(1, q) 1 1 1 1 0 0 0 0 y_(3, q) 0 0 1 1 1 1 0 0 y_(5, q) 0 1 1 0 0 1 1 0 Im(z_(q)) −7 −5 −3 −1 1 3 5 7

TABLE 39 y_(0, q) 1 1 1 1 1 1 1 1 0 0 0 0 0 0 0 0 y_(2, q) 0 0 0 0 1 1 1 1 1 1 1 1 0 0 0 0 y_(4, q) 0 0 1 1 1 1 0 0 0 0 1 1 1 1 0 0 y_(6, q) 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 Re(z_(q)) −15 −13 −11 −9 −7 −5 −3 −1 1 3 5 7 9 11 13 15

TABLE 40 y_(1, q) 1 1 1 1 1 1 1 1 0 0 0 0 0 0 0 0 y_(3, q) 0 0 0 0 1 1 1 1 1 1 1 1 0 0 0 0 y_(5, q) 0 0 1 1 1 1 0 0 0 0 1 1 1 1 0 0 y_(7, q) 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 Im(z_(q)) −15 −13 −11 −9 −7 −5 −3 −1 1 3 5 7 9 11 13 15

Tables 33 and 34 are used for determining a real number component Re(z_(q)) and an imaginary number component Im(z_(q)) when the modulation is performed in a QPSK method, Tables 35 and 36 are used for determining a real number component Re(z_(q)) and an imaginary number component Im(z_(q)) when the modulation is performed in a 16-QAM method, Tables 37 and 38 are used for determining a real number component Re(z_(q)) and an imaginary number component Im(z_(q)) when the modulation is performed in a 64-QAM method, and Tables 39 and 40 are used for determining a real number component Re(z_(q)) and an imaginary number component Im(z_(q)) when the modulation is performed in a 256-QAM method.

Referring to Tables 33 to 40, performance (e.g., reliability) varies according to whether a plurality of bits constituting a modulation symbol correspond to most significant bits (MSBs) or least significant bits (LSBs).

For example, in the case of 16-QAM, from among four (4) bits constituting a modulation symbol, each of the first and second bits determines a sign of each of the real number component Re(z_(q)) and the imaginary number component Im(z_(q)) of a constellation point onto which a modulation symbol is mapped, and the third and fourth bits determine a size of the constellation point onto which the modulation symbol is mapped.

In this case, the first and second bits for determining the sign from among the four (4) bits constituting the modulation symbol have a higher reliability than the third and fourth bits for determining the size.

In another example, in the case of 64-QAM, from among six (6) bits constituting a modulation symbol, each of the first and second bits determines a sign of each of the real number component Re(z_(q)) and the imaginary number component Im(z_(q)) of a constellation point onto which the modulation symbol is mapped. In addition, the third to sixth bits determine a size of the constellation point onto which the modulation symbol is mapped. From among these bits, the third and fourth bits determine a relatively large size, and the fifth and sixth bits determine a relatively small size (for example, the third bit determines which of sizes (−7, −5) and (−3, −1) corresponds to the constellation point onto which the modulation symbol is mapped, and, when (−7, −5) is determined by the third bit, the fourth bit determines which of −7 and −5 corresponds to the size of the constellation point.).

In this case, the first and second bits for determining the sign from among the six bits constituting the modulation symbol have the highest reliability, and the third and fourth bits for determining the relatively large size has the higher reliability than the fifth and sixth bits for determining the relatively small size.

As described above, in the case of the uniform constellation method, the bits constituting a modulation symbol have different reliability according to mapping locations in the modulation symbol.

The modulator 130 may modulate by mapping cells output from the demultiplexer (not shown) onto constellation points in a non-uniform constellation (NUC) method.

Specifically, the modulator 130 may modulate bits output from the demultiplexer (not shown) in various modulation methods such as non-uniform 16-QAM, non-uniform 64-QAM, non-uniform 256-QAM, non-uniform 1024-QAM, non-uniform 4096-QAM, etc.

Hereinafter, a method for generating a modulation symbol by using the non-uniform constellation method according to an exemplary embodiment will be explained.

First, the non-uniform constellation method has the following characteristics:

In the non-uniform constellation method, the constellation points may not regularly be arranged unlike in the uniform constellation method. Accordingly, when the non-uniform constellation method is used, performance for a signal-to-noise ratio (SNR) less than a specific value can be improved and a high SNR gain can be obtained in comparison to the uniform constellation method.

In addition, the characteristics of the constellation may be determined by one or more parameters such as a distance between constellation points. Since the constellation points are regularly distributed in the uniform constellation, the number of parameters for specifying the uniform constellation method may be one (1). However, the number of parameters necessary for specifying the non-uniform constellation method is relatively larger and the number of parameters increases as the constellation (e.g., the number of constellation points) increases.

In the case of the non-uniform constellation method, an x-axis and a y-axis may be designed to be symmetric to each other or may be designed to be asymmetric to each other. When the x-axis and the y-axis are designed to be asymmetric to each other, improved performance can be guaranteed, but decoding complexity may increase.

Hereinafter, an example of a case in which the x-axis and the y-axis are designed to be asymmetric to each other will be explained. In this case, once a constellation point of the first quadrant is defined, locations of constellation points in the other three quadrants may be determined as follows. For example, when a set of constellation points defined for the first quadrant is X, the set becomes −conj(X) in the case of the second quadrant, becomes conj(X) in the case of the third quadrant, and becomes −(X) in the case of the fourth quadrant.

That is, once the first quadrant is defined, the other quadrants may be expressed as follows:

-   -   1 Quarter (first quadrant)=X     -   2 Quarter (second quadrant)=−conj(X)     -   3 Quarter (third quadrant)=conj(X)     -   4 Quarter (fourth quadrant)=−X

Specifically, when the non-uniform M-QAM is used, M number of constellation points may be defined as z={z₀, z₁, . . . , z_(M−1)}. In this case, when the constellation points existing in the first quadrant are defined as {x₀, x₁, x₂, . . . , x_(M/4−1)}, z may be defined as follows:

-   -   from z₀ to z_(M/4−1)=from x₀ to X_(M/4)     -   from z_(M/4) to z_(2×M/4−1)=−conj(from x₀ to x_(M/4))     -   from z_(2×M/4) to z_(3×M/4−1)=conj(from x₀ to x_(M/4))     -   from z_(3×M/4) to z_(4×M/4−1)=−(from x₀ to x_(M/4))

Accordingly, the modulator 130 may map the bits [y₀, . . . , y_(m−1)] output from the demultiplexer (not shown) onto constellation points in the non-uniform constellation method by mapping the output bits onto z_(L) having an index of

$L = {\overset{m - 1}{\sum\limits_{i = 0}}{\left( {y_{1} \times 2^{m - 1}} \right).}}$

An example of the constellation of the non-uniform constellation method is illustrated in FIGS. 15 to 19.

An example of the method for modulating asymmetrically in the non-uniform constellation method in the modulator 130 is illustrated as in Tables 41 to 43 presented below. That is, according to an exemplary embodiment, modulation is performed in the non-uniform constellation method by defining constellation points existing in the first quadrant and defining constellations points existing in the other quadrants based on Tables 41 to 43.

TABLE 41 x/Shape R6/15 R7/15 R8/15 R9/15 R10/15 x0 0.4530 + 0.2663i 1.2103 + 0.5026i 0.4819 + 0.2575i 0.4909 + 1.2007i 0.2173 + 0.4189i x1 0.2663 + 0.4530i 0.5014 + 1.2103i 0.2575 + 0.4819i 1.2007 + 0.4909i 0.6578 + 0.2571i x2 1.2092 + 0.5115i 0.4634 + 0.2624i 1.2068 + 0.4951i 0.2476 + 0.5065i 0.4326 + 1.1445i x3 0.5115 + 1.2092i 0.2624 + 0.4627i 0.4951 + 1.2068i 0.5053 + 0.2476i 1.2088 + 0.5659i x/Shape R11/15 R12/15 R13/15 x0 0.9583 + 0.9547i 0.2999 + 0.2999i 0.9517 + 0.9511i x1 0.9547 + 0.2909i 0.9540 + 0.2999i 0.9524 + 0.3061i x2 0.2921 + 0.9583i 0.2999 + 0.9540i 0.3067 + 0.9524i x3 0.2909 + 0.2927i 0.9540 + 0.9540i 0.3061 + 0.3067i

TABLE 42 x/Shape R64_6/15 R64_7/15 R64_8/15 R64_9/15 R64_10/15 x0 0.4387 + 1.6023i 0.3352 + 0.6028i 1.4827 + 0.2920i 0.3547 + 0.6149i 1.4388 + 0.2878i x1 1.6023 + 0.4387i 0.2077 + 0.6584i 1.2563 + 0.8411i 0.1581 + 0.6842i 1.2150 + 0.8133i x2 0.8753 + 1.0881i 0.1711 + 0.3028i 1.0211 + 0.2174i 0.1567 + 0.2749i 1.0386 + 0.2219i x3 1.0881 + 0.8753i 0.1556 + 0.3035i 0.8798 + 0.5702i 0.1336 + 0.2700i 0.8494 + 0.6145i x4 0.2202 + 0.9238i 0.6028 + 0.3345i 0.2920 + 1.4827i 0.6177 + 0.4030i 0.2931 + 1.4656i x5 0.2019 + 0.7818i 0.6577 + 0.2084i 0.8410 + 1.2563i 0.7262 + 0.1756i 0.8230 + 1.2278i x6 0.3049 + 0.8454i 0.3021 + 0.1711i 0.2174 + 1.0211i 0.3568 + 0.1756i 0.2069 + 1.0649i x7 0.2653 + 0.7540i 0.3028 + 0.1556i 0.5702 + 0.8798i 0.3771 + 0.1336i 0.5677 + 0.8971i x8 0.7818 + 0.2019i 0.5556 + 0.8922i 0.3040 + 0.1475i 0.5639 + 0.8864i 0.4119 + 0.1177i x9 0.9238 + 0.2202i 0.2352 + 1.0190i 0.3028 + 0.1691i 0.1980 + 1.0277i 0.3998 + 0.2516i x10 0.7540 + 0.2653i 0.8450 + 1.2619i 0.6855 + 0.1871i 0.8199 + 1.2515i 0.7442 + 0.1559i x11 0.8454 + 0.3049i 0.2922 + 1.4894i 0.6126 + 0.3563i 0.2854 + 1.4691i 0.5954 + 0.4328i x12 0.2675 + 0.2479i 0.8929 + 0.5549i 0.1475 + 0.3040i 0.8654 + 0.6058i 0.1166 + 0.1678i x13 0.2479 + 0.2675i 1.0197 + 0.2359i 0.1691 + 0.3028i 1.0382 + 0.2141i 0.1582 + 0.3325i x14 0.2890 + 0.2701i 1.2626 + 0.8457i 0.1871 + 0.6855i 1.2362 + 0.8416i 0.1355 + 0.7408i x15 0.2701 + 0.2890i 1.4894 + 0.2922i 0.3563 + 0.6126i 1.4663 + 0.2973i 0.3227 + 0.6200i x/Shape R64_11/15 R64_12/15 R64_13/15 x0 0.3317 + 0.6970i 1.0854 + 0.5394i 0.4108 + 0.7473i x1 0.1386 + 0.8824i 0.7353 + 0.4623i 0.1343 + 0.5338i x2 0.1323 + 0.4437i 1.0474 + 0.1695i 0.1570 + 0.9240i x3 0.1015 + 0.1372i 0.7243 + 0.1504i 0.1230 + 0.1605i x4 0.5682 + 0.4500i 1.0693 + 0.9408i 0.6285 + 0.4617i x5 0.6739 + 0.1435i 0.7092 + 0.8073i 0.3648 + 0.3966i x6 0.3597 + 0.3401i 1.4261 + 0.2216i 0.6907 + 0.1541i x7 0.3660 + 0.1204i 0.6106 + 1.1783i 0.3994 + 0.1308i x8 0.6004 + 0.8922i 0.1392 + 0.4078i 0.7268 + 0.8208i x9 0.2120 + 1.2253i 0.4262 + 0.4205i 1.0463 + 0.9495i x10 0.9594 + 1.0714i 0.1407 + 0.1336i 0.1866 + 1.2733i x11 0.5829 + 1.3995i 0.4265 + 0.1388i 0.5507 + 1.1793i x12 0.8439 + 0.5675i 0.1388 + 0.7057i 0.9283 + 0.5140i x13 0.9769 + 0.1959i 0.4197 + 0.7206i 1.2648 + 0.5826i x14 1.2239 + 0.6760i 0.1682 + 1.0316i 0.9976 + 0.1718i x15 1.3653 + 0.2323i 0.2287 + 1.3914i 1.3412 + 0.1944i

TABLE 43 x/Shape R6/15 R7/15 R8/15 R9/15 R10/15 x0 0.6800 + 1.6926i 1.2905 + 1.3099i 1.0804 + 1.3788i 1.3231 + 1.1506i 1.6097 + 0.1548i x1 0.3911 + 1.3645i 1.0504 + 0.9577i 1.0487 + 0.9862i 0.9851 + 1.2311i 1.5549 + 0.4605i x2 0.2191 + 1.7524i 1.5329 + 0.8935i 1.6464 + 0.7428i 1.1439 + 0.8974i 1.3226 + 0.1290i x3 0.2274 + 1.4208i 1.1577 + 0.8116i 1.3245 + 0.9414i 0.9343 + 0.9271i 1.2772 + 0.3829i x4 0.8678 + 1.2487i 1.7881 + 0.2509i 0.7198 + 1.2427i 1.5398 + 0.7962i 1.2753 + 1.0242i x5 0.7275 + 1.1667i 1.4275 + 0.1400i 0.8106 + 1.0040i 0.9092 + 0.5599i 1.4434 + 0.7540i x6 0.8747 + 1.0470i 1.4784 + 0.5201i 0.5595 + 1.0317i 1.2222 + 0.6574i 1.0491 + 0.8476i x7 0.7930 + 1.0406i 1.3408 + 0.4346i 0.6118 + 0.9722i 0.9579 + 0.6373i 1.1861 + 0.6253i x8 0.2098 + 0.9768i 0.7837 + 0.5867i 1.6768 + 0.2002i 0.7748 + 1.5867i 0.9326 + 0.0970i x9 0.2241 + 1.0454i 0.8250 + 0.6455i 0.9997 + 0.6844i 0.6876 + 1.2489i 0.8962 + 0.2804i x10 0.1858 + 0.9878i 0.8256 + 0.5601i 1.4212 + 0.4769i 0.5992 + 0.9208i 1.1044 + 0.1102i x11 0.1901 + 1.0659i 0.8777 + 0.6110i 1.1479 + 0.6312i 0.6796 + 0.9743i 1.0648 + 0.3267i x12 0.5547 + 0.8312i 1.0080 + 0.1843i 0.6079 + 0.6566i 0.5836 + 0.5879i 0.7325 + 0.6071i x13 0.5479 + 0.8651i 1.0759 + 0.1721i 0.7284 + 0.6957i 0.6915 + 0.5769i 0.8260 + 0.4559i x14 0.6073 + 0.8182i 1.0056 + 0.2758i 0.5724 + 0.7031i 0.5858 + 0.7058i 0.8744 + 0.7153i x15 0.5955 + 0.8420i 1.0662 + 0.2964i 0.6302 + 0.7259i 0.6868 + 0.6793i 0.9882 + 0.5300i x16 1.4070 + 0.1790i 0.8334 + 1.5554i 0.1457 + 1.4010i 1.6118 + 0.1497i 0.1646 + 1.6407i x17 1.7227 + 0.2900i 0.8165 + 1.1092i 0.1866 + 1.7346i 0.9511 + 0.1140i 0.4867 + 1.5743i x18 1.3246 + 0.2562i 0.6092 + 1.2729i 0.1174 + 1.1035i 1.2970 + 0.1234i 0.1363 + 1.3579i x19 1.3636 + 0.3654i 0.6728 + 1.1456i 0.1095 + 1.0132i 1.0266 + 0.1191i 0.4023 + 1.3026i x20 1.3708 + 1.2834i 0.3061 + 1.7469i 0.4357 + 1.3636i 1.5831 + 0.4496i 1.0542 + 1.2584i x21 1.6701 + 0.8403i 0.1327 + 1.4056i 0.5853 + 1.6820i 0.9328 + 0.3586i 0.7875 + 1.4450i x22 1.1614 + 0.7909i 0.3522 + 1.3414i 0.3439 + 1.0689i 1.2796 + 0.3894i 0.8687 + 1.0407i x23 1.2241 + 0.7367i 0.2273 + 1.3081i 0.3234 + 0.9962i 1.0188 + 0.3447i 0.6502 + 1.1951i x24 0.9769 + 0.1863i 0.5007 + 0.8098i 0.1092 + 0.6174i 0.5940 + 0.1059i 0.0982 + 0.9745i x25 0.9452 + 0.2057i 0.5528 + 0.8347i 0.1074 + 0.6307i 0.7215 + 0.1100i 0.2842 + 0.9344i x26 1.0100 + 0.2182i 0.4843 + 0.8486i 0.1109 + 0.6996i 0.5863 + 0.1138i 0.1142 + 1.1448i x27 0.9795 + 0.2417i 0.5304 + 0.8759i 0.1076 + 0.7345i 0.6909 + 0.1166i 0.3385 + 1.0973i x28 0.8241 + 0.4856i 0.1715 + 0.9147i 0.3291 + 0.6264i 0.5843 + 0.3604i 0.6062 + 0.7465i x29 0.8232 + 0.4837i 0.1540 + 0.9510i 0.3126 + 0.6373i 0.6970 + 0.3592i 0.4607 + 0.8538i x30 0.8799 + 0.5391i 0.1964 + 0.9438i 0.3392 + 0.6999i 0.5808 + 0.3250i 0.7263 + 0.8764i x31 0.8796 + 0.5356i 0.1788 + 0.9832i 0.3202 + 0.7282i 0.6678 + 0.3290i 0.5450 + 1.0067i x32 0.1376 + 0.3342i 0.3752 + 0.1667i 0.9652 + 0.1066i 0.1406 + 1.6182i 0.2655 + 0.0746i x33 0.1383 + 0.3292i 0.3734 + 0.1667i 0.9075 + 0.1666i 0.1272 + 1.2984i 0.2664 + 0.0759i x34 0.1363 + 0.3322i 0.3758 + 0.1661i 0.9724 + 0.1171i 0.1211 + 0.9644i 0.4571 + 0.0852i x35 0.1370 + 0.3273i 0.3746 + 0.1649i 0.9186 + 0.1752i 0.1220 + 1.0393i 0.4516 + 0.1062i x36 0.1655 + 0.3265i 0.4013 + 0.1230i 0.6342 + 0.1372i 0.1124 + 0.6101i 0.2559 + 0.1790i x37 0.1656 + 0.3227i 0.4001 + 0.1230i 0.6550 + 0.1495i 0.1177 + 0.6041i 0.2586 + 0.1772i x38 0.1634 + 0.3246i 0.4037 + 0.1230i 0.6290 + 0.1393i 0.1136 + 0.7455i 0.3592 + 0.2811i x39 0.1636 + 0.3208i 0.4019 + 0.1218i 0.6494 + 0.1504i 0.1185 + 0.7160i 0.3728 + 0.2654i x40 0.1779 + 0.6841i 0.6025 + 0.3934i 1.3127 + 0.1240i 0.4324 + 1.5679i 0.7706 + 0.0922i x41 0.1828 + 0.6845i 0.5946 + 0.3928i 0.9572 + 0.4344i 0.3984 + 1.2825i 0.7407 + 0.2260i x42 0.1745 + 0.6828i 0.6116 + 0.3879i 1.2403 + 0.2631i 0.3766 + 0.9534i 0.6180 + 0.0927i x43 0.1793 + 0.6829i 0.6019 + 0.3837i 1.0254 + 0.4130i 0.3668 + 1.0301i 0.6019 + 0.1658i x44 0.3547 + 0.6009i 0.7377 + 0.1618i 0.6096 + 0.4214i 0.3667 + 0.5995i 0.6007 + 0.4980i x45 0.3593 + 0.6011i 0.7298 + 0.1582i 0.6773 + 0.4284i 0.3328 + 0.5960i 0.6673 + 0.3928i x46 0.3576 + 0.5990i 0.7274 + 0.1782i 0.5995 + 0.4102i 0.3687 + 0.7194i 0.4786 + 0.3935i x47 0.3624 + 0.5994i 0.7165 + 0.1746i 0.6531 + 0.4101i 0.3373 + 0.6964i 0.5176 + 0.3391i x48 0.2697 + 0.1443i 0.1509 + 0.2425i 0.1250 + 0.1153i 0.1065 + 0.1146i 0.0757 + 0.1003i x49 0.2704 + 0.1433i 0.1503 + 0.2400i 0.1252 + 0.1158i 0.1145 + 0.1108i 0.0753 + 0.1004i x50 0.2644 + 0.1442i 0.1515 + 0.2437i 0.1245 + 0.1152i 0.1053 + 0.1274i 0.0777 + 0.4788i x51 0.2650 + 0.1432i 0.1503 + 0.2425i 0.1247 + 0.1156i 0.1134 + 0.1236i 0.0867 + 0.4754i x52 0.2763 + 0.1638i 0.1285 + 0.2388i 0.3768 + 0.1244i 0.1111 + 0.3821i 0.1023 + 0.2243i x53 0.2768 + 0.1626i 0.1279 + 0.2419i 0.3707 + 0.1237i 0.1186 + 0.3867i 0.1010 + 0.2242i x54 0.2715 + 0.1630i 0.1279 + 0.2431i 0.3779 + 0.1260i 0.1080 + 0.3431i 0.1950 + 0.3919i x55 0.2719 + 0.1618i 0.1279 + 0.2406i 0.3717 + 0.1252i 0.1177 + 0.3459i 0.1881 + 0.3969i x56 0.6488 + 0.1696i 0.3394 + 0.5764i 0.1161 + 0.3693i 0.3644 + 0.1080i 0.0930 + 0.8122i x57 0.6462 + 0.1706i 0.3364 + 0.5722i 0.1157 + 0.3645i 0.3262 + 0.1104i 0.2215 + 0.7840i x58 0.6456 + 0.1745i 0.3328 + 0.5758i 0.1176 + 0.3469i 0.3681 + 0.1173i 0.0937 + 0.6514i x59 0.6431 + 0.1753i 0.3303 + 0.5698i 0.1171 + 0.3424i 0.3289 + 0.1196i 0.1540 + 0.6366i x60 0.5854 + 0.3186i 0.1491 + 0.6316i 0.3530 + 0.3899i 0.3665 + 0.3758i 0.4810 + 0.6306i x61 0.5862 + 0.3167i 0.1461 + 0.6280i 0.3422 + 0.3808i 0.3310 + 0.3795i 0.3856 + 0.7037i x62 0.5864 + 0.3275i 0.1509 + 0.6280i 0.3614 + 0.3755i 0.3672 + 0.3353i 0.3527 + 0.5230i x63 0.5873 + 0.3254i 0.1473 + 0.6225i 0.3509 + 0.3656i 0.3336 + 0.3402i 0.3100 + 0.5559i x/Shape R11/15 R12/15 R13/15 x0 0.3105 + 0.3382i 1.1014 + 1.1670i 0.3556 + 0.3497i x1 0.4342 + 0.3360i 0.8557 + 1.2421i 0.3579 + 0.4945i x2 0.3149 + 0.4829i 1.2957 + 0.8039i 0.5049 + 0.3571i x3 0.4400 + 0.4807i 1.0881 + 0.8956i 0.5056 + 0.5063i x4 0.1811 + 0.3375i 0.5795 + 1.2110i 0.2123 + 0.3497i x5 0.0633 + 0.3404i 0.6637 + 1.4215i 0.2116 + 0.4900i x6 0.1818 + 0.4851i 0.6930 + 1.0082i 0.0713 + 0.3489i x7 0.0633 + 0.4815i 0.8849 + 0.9647i 0.0690 + 0.4960i x8 0.3084 + 0.1971i 1.2063 + 0.5115i 0.3527 + 0.2086i x9 0.4356 + 0.1993i 1.0059 + 0.4952i 0.3497 + 0.0713i x10 0.3098 + 0.0676i 1.4171 + 0.5901i 0.4960 + 0.2123i x11 0.4342 + 0.0691i 1.0466 + 0.6935i 0.4974 + 0.0698i x12 0.1775 + 0.1985i 0.6639 + 0.6286i 0.2086 + 0.2079i x13 0.0640 + 0.1978i 0.8353 + 0.5851i 0.2094 + 0.0690i x14 0.1775 + 0.0676i 0.6879 + 0.8022i 0.0676 + 0.2079i x15 0.0647 + 0.0669i 0.8634 + 0.7622i 0.0698 + 0.0683i x16 0.7455 + 0.3411i 0.1213 + 1.4366i 0.3586 + 0.7959i x17 0.5811 + 0.3396i 0.1077 + 1.2098i 0.3571 + 0.6392i x18 0.7556 + 0.4669i 0.0651 + 0.9801i 0.5034 + 0.8271i x19 0.5862 + 0.4756i 0.2009 + 1.0115i 0.5063 + 0.6600i x20 0.9556 + 0.3280i 0.3764 + 1.4264i 0.2146 + 0.7862i x21 1.1767 + 0.3091i 0.3237 + 1.2130i 0.2109 + 0.6340i x22 0.9673 + 0.4720i 0.5205 + 0.9814i 0.0713 + 0.8093i x23 1.2051 + 0.5135i 0.3615 + 1.0163i 0.0698 + 0.6467i x24 0.7367 + 0.2015i 0.0715 + 0.6596i 0.2799 + 1.0862i x25 0.5811 + 0.2015i 0.2116 + 0.6597i 0.2806 + 1.2755i x26 0.7316 + 0.0669i 0.0729 + 0.8131i 0.4328 + 0.9904i x27 0.5782 + 0.0669i 0.2158 + 0.8246i 0.4551 + 1.1812i x28 0.9062 + 0.1971i 0.5036 + 0.6467i 0.2309 + 0.9414i x29 1.2829 + 0.1185i 0.3526 + 0.6572i 0.1077 + 1.3891i x30 0.9156 + 0.0735i 0.5185 + 0.8086i 0.0772 + 0.9852i x31 1.1011 + 0.0735i 0.3593 + 0.8245i 0.0802 + 1.1753i x32 0.3244 + 0.8044i 1.2545 + 0.1010i 0.8301 + 0.3727i x33 0.4589 + 0.8218i 1.0676 + 0.0956i 0.8256 + 0.5256i x34 0.3207 + 0.6415i 1.4782 + 0.1167i 0.6593 + 0.3668i x35 0.4509 + 0.6371i 0.8981 + 0.0882i 0.6623 + 0.5182i x36 0.1920 + 0.8196i 0.5518 + 0.0690i 1.0186 + 0.3645i x37 0.0633 + 0.8167i 0.6903 + 0.0552i 1.0001 + 0.5242i x38 0.1811 + 0.6371i 0.5742 + 0.1987i 1.1857 + 0.2725i x39 0.0640 + 0.6415i 0.7374 + 0.1564i 1.3928 + 0.3408i x40 0.3331 + 1.0669i 1.2378 + 0.3049i 0.8011 + 0.2227i x41 0.4655 + 1.0087i 1.0518 + 0.3032i 0.7981 + 0.0735i x42 0.3433 + 1.2865i 1.4584 + 0.3511i 0.6459 + 0.2198i x43 0.5004 + 1.5062i 0.9107 + 0.2603i 0.6430 + 0.0713i x44 0.1971 + 1.0051i 0.6321 + 0.4729i 0.9681 + 0.2205i x45 0.0735 + 1.0298i 0.7880 + 0.4392i 0.9615 + 0.0735i x46 0.1498 + 1.5018i 0.6045 + 0.3274i 1.3327 + 0.1039i x47 0.0865 + 1.2553i 0.7629 + 0.2965i 1.1359 + 0.0809i x48 0.7811 + 0.8080i 0.0596 + 0.0739i 0.8382 + 0.8709i x49 0.6167 + 0.8153i 0.1767 + 0.0731i 0.8145 + 0.6934i x50 0.7636 + 0.6255i 0.0612 + 0.2198i 0.6645 + 0.8486i x51 0.6000 + 0.6327i 0.1815 + 0.2192i 0.6600 + 0.6786i x52 0.9898 + 0.7680i 0.4218 + 0.0715i 1.1612 + 0.6949i x53 1.5855 + 0.1498i 0.2978 + 0.0725i 0.9785 + 0.6942i x54 0.9476 + 0.6175i 0.4337 + 0.2115i 1.3698 + 0.6259i x55 1.4625 + 0.4015i 0.3057 + 0.2167i 1.2183 + 0.4841i x56 0.8276 + 1.0225i 0.0667 + 0.5124i 0.7989 + 1.0498i x57 0.6313 + 1.0364i 0.2008 + 0.5095i 0.4395 + 1.4203i x58 0.8815 + 1.2865i 0.0625 + 0.3658i 0.6118 + 1.0246i x59 0.6342 + 1.2705i 0.1899 + 0.3642i 0.6303 + 1.2421i x60 1.0422 + 0.9593i 0.4818 + 0.4946i 1.0550 + 0.8924i x61 1.2749 + 0.8538i 0.3380 + 0.5050i 0.8612 + 1.2800i x62 1.1556 + 1.1847i 0.4571 + 0.3499i 1.2696 + 0.8969i x63 1.4771 + 0.6742i 0.3216 + 0.3599i 1.0342 + 1.1181i

Table 41 indicates non-uniform 16-QAM, Table42 indicates non-uniform 64-QAM, and table 43 indicates non-uniform 256-QAM, and different mapping methods may be applied according to a code rate.

On the other hand, when the non-uniform constellation is designed to have the x-axis and the y-axis symmetric to each other, constellation points may be expressed similarly to those of uniform QAM and an example is illustrated as in Tables 44 to 46 presented below:

TABLE 44 y_(0, q) 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 y_(2, q) 0 0 0 0 0 0 0 0 1 1 1 1 1 1 1 1 y_(4, q) 0 0 0 0 1 1 1 1 1 1 1 1 0 0 0 0 y_(6, q) 0 0 1 1 1 1 0 0 0 0 1 1 1 1 0 0 y_(8, q) 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 Re(z_(q)) −x₁₅ −x₁₄ −x₁₃ −x₁₂ −x₁₁ −x₁₀ −x₉ −x₈ −x₇ −x₆ −x₅ −x₄ −x₃ −x₂ −x₁ −1  y_(0, q) 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 y_(2, q) 1 1 1 1 1 1 1 1 0 0 0 0 0 0 0 0 y_(4, q) 0 0 0 0 1 1 1 1 1 1 1 1 0 0 0 0 y_(6, q) 0 0 1 1 1 1 0 0 0 0 1 1 1 1 0 0 y_(8, q) 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 Re(z_(q)) 1  x₁  x₂  x₃  x₄  x₅  x₆  x₇  x₈  x₉  x₁₀  x₁₁  x₁₂  x₁₃  x₁₄ x₁₅

TABLE 45 y_(1, q) 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 y_(3, q) 0 0 0 0 0 0 0 0 1 1 1 1 1 1 1 1 y_(5, q) 0 0 0 0 1 1 1 1 1 1 1 1 0 0 0 0 y_(7, q) 0 0 1 1 1 1 0 0 0 0 1 1 1 1 0 0 y_(9, q) 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 Im(z_(q)) −x₁₅ −x₁₄ −x₁₃ −x₁₂ −x₁₁ −x₁₀ −x₉ −x₈ −x₇ −x₆ −x₅ −x₄ −x₃ −x₂ −x₁ −1  y_(1, q) 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 y_(3, q) 1 1 1 1 1 1 1 1 0 0 0 0 0 0 0 0 y_(5, q) 0 0 0 0 1 1 1 1 1 1 1 1 0 0 0 0 y_(7, q) 0 0 1 1 1 1 0 0 0 0 1 1 1 1 0 0 y_(9, q) 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 Im(z_(q)) 1  x₁  x₂  x₃  x₄  x₅  x₆  x₇  x₈  x₉  x₁₀  x₁₁  x₁₂  x₁₃  x₁₄ x₁₅

TABLE 46 x/Shape R6/15 R7/15 R8/15 R9/15 R10/15 R11/15 R12/15 R13/15 x1 1.0003 1 1.0005 1 1.0772 1.16666667 2.5983 2.85714286 x2 1.0149 1.04 2.0897 2.78571429 2.8011 3.08333333 4.5193 4.85714286 x3 1.0158 1.04 2.0888 2.78571429 2.9634 3.33333333 6.1649 6.85714286 x4 2.6848 3 3.995 4.85714286 4.8127 5.16666667 8.2107 8.85714286 x5 2.6903 3.04 3.9931 4.85714286 5.1864 5.75 9.9594 11 x6 2.882 3.28 5.3843 6.85714286 6.7838 7.41666667 12.0321 13.2857143 x7 2.8747 3.32 5.3894 6.85714286 7.5029 8.5 13.9574 15.7142857 x8 4.7815 5.24 7.5206 9.14285714 9.238 10.0833333 16.2598 18.1428571 x9 4.7619 5.32 7.6013 9.28571429 10.32 11.5833333 18.4269 20.7142857 x10 5.5779 6.04 9.3371 11.5714286 12.0115 13.3333333 20.9273 23.4285714 x11 5.6434 6.28 9.8429 12.2142857 13.5356 15.25 23.4863 26.2857143 x12 7.3854 8.24 11.9255 14.6428571 15.6099 17.3333333 26.4823 29.2857143 x13 7.8797 8.84 13.3962 16.4285714 17.7524 19.75 29.7085 32.4285714 x14 9.635 11.04 15.8981 19.4285714 20.5256 22.4166667 33.6247 35.7142857 x15 11.7874 13.68 19.1591 23.2857143 24.1254 25.5833333 38.5854 39.4285714

Tables 44 and 45 are tables for determining the real number component Re(z_(q)) and the imaginary number component Im(z_(q)) when modulation is performed in the non-uniform 1024-QAM method. That is, Table 44 indicates the real number part of the 1024-QAM, and Table 45 indicates the imaginary number part of the 1024-QAM. In addition, Table 46 illustrate an example of a case in which modulation is performed in the non-uniform 1024-QAM method, and show x, values of Tables 44 and 45.

Since the non-uniform constellation method asymmetrically map the modulation symbol onto the constellation point as shown in Tables 44 to 46, modulation symbols mapped onto constellation points may have different decoding performance. That is, bits constituting a modulation symbol may have different performance.

For example, referring to FIG. 15 illustrating an example of a case in which modulation is performed in the non-uniform 64-QAM method, a modulation symbol 10 may be configured as (y₀, y₁, y₂, y₃, y₄, y₅)=(0, 0, 1, 0, 1, 0), and performance (e.g., capacity) of bits constituting the modulation symbol 10 may have a relationship of C(y₀)>C(y₁)>C(y₂)>C(y₃)>C(y₄)>C(y₅).

In addition, it is obvious that the constellation in the uniform constellation method and the non-uniform constellation method may be rotated and/or scaled (herein, the same or different scaling factor may be applied to a real number axis and an imaginary number axis), and other variations can be applied. In addition, the illustrated constellation indicates relevant locations of the constellation points and another constellation can be derived by rotation, scaling and/or other appropriate conversion.

As described above, the modulator 130 may map modulation symbols onto constellation points by using uniform constellation methods and non-uniform constellation methods. In this case, bits constituting a modulation symbol may have different performance as described above.

LDPC codeword bits may have different codeword characteristics according to a configuration of a parity check matrix. That is, the LDPC codeword bits may have different codeword characteristics according to the number of 1 existing in the columns of the parity check matrix, that is, a column degree.

Accordingly, the interleaver 120 may interleave to map the LDPC codeword bits onto modulation symbols by considering both the codeword characteristic of the LDPC codeword bits and the reliability of the bits constituting a modulation symbol.

In particular, since bits constituting a modulation symbol have different performance when a non-uniform QAM is used, the block interleaver 124 configures the number of columns to be identical to the number of bits constituting a modulation symbol such that one of a plurality of groups of an LDPC codeword can be mapped onto bits each of which exists on a same location of each modulation symbol.

That is, when LDPC codeword bits of high decoding performance are mapped onto high reliability bits from among bits of each modulation symbol, a receiver side may show high decoding performance, but there is a problem that the LDPC codeword bits of the high decoding performance are not received. In addition, when the LDPC codeword bits of high decoding performance are mapped onto low reliability bits from among the bits of the modulation symbol, initial reception performance is excellent, and thus, overall performance is also excellent. However, when many bits showing poor decoding performance are received, error propagation may occur.

Accordingly, when LDPC codeword bits are mapped onto modulation symbols, an LDPC codeword bit having a specific codeword characteristic is mapped onto a specific bit of a modulation symbol by considering both codeword characteristics of the LDPC codeword bits and reliability of the bits of the modulation symbol, and is transmitted to a receiver side. Accordingly, the receiver side can achieve both the high reception performance and the high decoding performance.

In this case, since the LDPC codeword is divided into groups each formed of M (=360) number of bits having the same codeword characteristic and the bits are mapped respectively onto a bit of a specific location of each modulation symbol in group units, bits having a specific codeword characteristic can be mapped onto the specific location of each modulation symbol more effectively. In addition, the number of bits constituting the group may be an aliquot part of M as described above. However, the number of codeword bits constituting the group is limited to M for convenience of explanation.

That is, the modulator 130 can map at least one bit included in a predetermined group from among the plurality of groups constituting the LDPC codeword onto a predetermined bit of each modulation symbol. Herein, each of the plurality of groups may be formed of M (=360) number of bits.

For example, in the case of 16-QAM, at least one bit included in a predetermined group from among the plurality of groups may be mapped onto a first bit of each modulation symbol, or may be mapped onto a first bit and a second bit.

The modulator 130 can map at least one bit included in a predetermined group from among the plurality of groups onto a predetermined bit of each modulation symbol for the following reasons.

As described above, the block interleaver 124 interleaves a plurality of groups of an LDPC codeword in group units, the demultiplexer (not shown) demultiplexes bits output from the block interleaver 124, and the modulator 130 maps demultiplexed bits (that is, cells) onto modulation symbols serially.

Accordingly, the group interleaver 122, which is placed before the block interleaver 124, interleaves the LDPC codeword in group units such that groups including bits to be mapped onto bits of specific locations of a modulation symbol can be written in the same column of the block interleaver 124, considering a demultiplexing operation of the demultiplexer (not shown).

Specifically, the group interleaver 122 may rearrange the order of a plurality of groups of an LDPC codeword in group units such that at least one group including bits to be mapped onto the same location of different modulation symbols are serially arranged adjacent to one another, thereby allowing the block interleaver 122 to write a predetermined group on a predetermined column. That is, the group interleaver 122 interleaves the plurality of groups of the LDPC codeword in group units based on the above-described Tables 21 to 25, so that at least one group including bits to be mapped onto the same location of each modulation symbol are arranged to be adjacent to one another, and the block interleaver 124 interleaves by writing the adjacent at least one group on the same column.

Accordingly, the modulator 130 may generate a modulation symbol by mapping a bit output from a predetermined column of the block interleaver 124 onto a predetermined bit of the modulation symbol. In this case, bits included in one group may be mapped onto one bit of each modulation symbol or may be mapped onto two bits of each modulation symbol.

To explain detail, a case in which an LDPC codeword having a length of 16200 is modulated in the non-uniform 64-QAM method will be explained.

The group interleaver 122 divides the LDPC codeword into 16200/360(=45) groups, and interleaves the plurality of groups in group units.

In this case, the group interleaver 122 determines the number of groups to be written in each column of the block interleaver 124 based on the number of columns of the block interleaver 124, and interleaves the plurality of groups in group units based on the determined number of groups.

Herein, groups written in a same column of the block interleaver 124 may be mapped onto a single specific bit or two specific bits from among bits constituting each modulation symbol according to the number of columns of the block interleaver 124. Thus, the group interleaver 122 interleaves the plurality of groups in group units such that groups including bits required to be mapped onto a predetermined bit of each modulation symbol are adjacent to one another and serially arranged, considering bit characteristic of the modulation symbol. In this case, the group interleaver 122 may use the above-described Table 22.

Accordingly, the groups which are adjacent to one another in the LDPC codeword interleaved in group units may be written in the same column of the block interleaver 124, and the bits written in the same column may be mapped onto a single specific bit or two specific bits of each modulation symbol by the modulator 130.

For example, it is assumed that the block interleaver 124 includes as many columns as the number of bits constituting a modulation symbol, that is, six (6) columns. In this case, each column of the block interleaver 124 may be divided into a first part including 2520 rows and a second part including 180 rows, as shown in Table 30.

Accordingly, the group interleaver 122 performs group interleaving such that 2520/360(=7) groups to be written in the first part of each column of the block interleaver 124 from among the plurality of groups are serially arranged to be adjacent to one another. Accordingly, the block interleaver 124 writes the seven (7) groups on the first part of each column and divides the bits included in the other three (3) groups and writes these bits on the second part of each column.

Thereafter, the block interleaver 124 reads the bits written in each row of the first part of the plurality of columns in the row direction, and reads the bits written in each row of the second part of the plurality of columns in the row direction.

That is, the block interleaver 124 may output the bits written in each row of the plurality of columns, from the bit written in the first row of the first column to the bit written in the first row of the sixth column, sequentially like (q₀,q₁,q₂,q₃,q₄,q₅,q₆,q₇,q₈,q₉,q₁₀,q₁₁, . . . ).

In this case, when the demultiplexer (not shown) is not used or the demultiplexer (not shown) outputs serially bits input to the demultiplexer (not shown) without changing the order of the bits, the LDPC codeword bits output from the block interleaver 124, (q₀,q₁,q₂,q₃,q₄,q₅), (q₆,q₇,q₈,q₉,q₁₀,q₁₁), . . . , etc. are modulated by the modulator 130. That is, the LDPC codeword bits output from the block interleaver 124, (q₀,q₁,q₂,q₃,q₄,q5), (q₆,q₇,q₈,q₉,q₁₀,q₁₁), . . . , etc. configure cells (y_(0,0),y_(1,0), . . . ,y_(5,0)), (y_(0,1),y_(1,1), . . . ,y_(5,1)), . . . , etc. and the modulator 130 generates a modulation symbol by mapping the cells onto constellation points.

Accordingly, the modulator 130 may map bits output from a same column of the block interleaver 124 onto a single specific bit of bits constituting each modulation symbol. For example, the modulator 130 may map bits included in a group written in the first column of the block interleaver 124, that is, (q₀, q₆, . . . ), onto the first bit of each modulation symbol, and also, bits written in the first column may be bits which are determined to be mapped onto the first bit of each modulation symbol according to a codeword characteristic of the LDPC codeword bits and the reliability of the bits constituting the modulation symbol.

As described above, the group interleaver 122 may interleave a plurality of groups of an LDPC codeword in group units such that the groups including bits to be mapped onto a single bit of a specific location of each modulation symbol are written in a specific column of the block interleaver 124.

On the other hand, it is assumed that the block interleaver 124 includes as many columns as half of the number of bits constituting a modulation symbol, that is, three (3) columns. In this case, each column of the block interleaver 124 is not divided into parts as shown in Table 29 and 5400 bits are written in each column.

Accordingly, the group interleaver 122 performs group interleaving such that 5400/360(=15) groups to be written in each column of the block interleaver 124 from among the plurality of groups are serially arranged to be adjacent to one another. Accordingly, the block interleaver 124 writes the 15 groups on each column.

Thereafter, the block interleaver 124 may read bits written in each row of the plurality of columns in the row direction.

That is, the block interleaver 124 may output the bits written in each row of the plurality of columns, from the bit written in the first row of the first column to the bit written in the first row of the third column, sequentially like (q₀,q₁,q₂,q₃,q₄,q₅,q₆,q₇,q₈,q₉,q₁₀,q₁₁, . . . ).

In this case, the demultiplexer (not shown) demultiplexes the LDPC codeword bits output from the block interleaver 124 based on Table 32, and output cells likes (y_(0,0),y_(1,0), . . . ,y_(5,0))=(q₀,q₂,q₄,q₁,q₃,q₅), (y_(0,1),y_(1,1), . . . ,y_(5,1))=(q₆,q₈,q₁₀,q₇,q₉,q₁₁), . . . , etc. and the modulator 130 generates a modulation symbol by mapping the cells onto constellation points.

Accordingly, the modulator 130 may map bits output from the same column of the block interleaver 124 onto two specific bits of each modulation symbol. For example, the modulator 130 may map (q₀, q₆, . . . ) from among the bits (q₀, q₃, q₆, q₉, . . . ) included in the group written in the first column in the block interleaver 124 onto the first bit of each modulation symbol, and may map (q₃, q₉, . . . ) on the fifth bit of each modulation symbol. The bits written in the first column are bits which are determined to be mapped onto the first bit and the fifth bit of each modulation symbol according to the codeword characteristic of the LDPC codeword bits and the reliability of the bits constituting the modulation symbol. Herein, the first bit of the modulation symbol is a bit for determining a sign of the real number component Re(z_(q)) of a constellation point onto which the modulation symbol is mapped, and the fifth bit of the modulation symbol is a bit for determining a relatively small size of the constellation point onto which the modulation symbol is mapped.

As described above, the group interleaver 122 may interleave the plurality of groups of the LDPC codeword in group units such that groups including bits to be mapped onto two bits of specific locations of a modulation symbol are written in a specific column of the block interleaver 124.

Hereinafter, it is assumed that the encoder 110 performs LDPC encoding at a code rate of 10/15, 11/15, 12/15, and 13/15 and generates an LDPC codeword (N_(ldpc)=16200) formed of 16200 bits, and the modulator 130 uses the non-uniform 16-QAM modulation method corresponding to the code rate based on table 21.

Hereinafter, exemplary embodiments will be explained in detail.

First, according to a first exemplary embodiment, it is assumed that the encoder 110 performs LDPC encoding at a code rate of 10/15, 11/15, 12/15 and 13/15 and generates an LDPC codeword formed of 16200 bits (N_(ldpc)=16200), and the modulator 130 uses the non-uniform 16-QAM modulation method corresponding to the code rate based on Table 41.

In this case, the group interleaver 122 may perform group interleaving by using Equation 11 and Table 21. The block interleaver 124 in which the number of columns is four (4), the number of rows of the first part is 3960(=360×11), and the number of rows of the second part is 180 according to Table 26 or 30 may be used.

Accordingly, 11 groups (X₃₅, X₃₁, X₃₉, X₁₉, X₂₉, X₂₀, X₃₆, X₀, X₉, X₁₃, X₅) constituting an LDPC codeword are input to the first part of the first column of the block interleaver 124, 11 groups (X₃₇, X₁₇, X₄₃, X₂₁, X₄₁, X₂₅, X₁, X₃₃, X₂₄, X₁₂, X₃₀) are input to the first part of the second column of the block interleaver 124, 11 groups (X₁₆, X₃₂, X₁₀, X₂₈, X₄, X₂₆, X₈, X₄₀, X₄₂, X₃, X₆) are input to the first part of the third column of the block interleaver 124, and 11 groups (X₂, X₃₈, X₁₄, X₃₄, X₂₂, X₁₈, X₂₇, X₂₃, X₇, X₁₁, X₁₅) are input to the first part of the fourth column of the block interleaver 124.

In addition, a group X₄₄ is input to the second part of the block interleaver 124. Specifically, bits constituting the group X₄₄ are input to the rows of the first column of the second part serially, input to the rows of the second column serially, input to the rows of the third column serially, and finally input to the rows of the fourth column serially. In this case, the group X₄₄ is formed of 360 bits and 90 bits are input to the second part of each column.

In addition, the block interleaver 124 may output the bits input to the first row to the last row of each column serially, and the bits output from the block interleaver 124 may be input to the modulator 130 serially. In this case, the demultiplexer (not shown) may be omitted or the demultiplexer (not shown) may output the input bits serially without changing the order of the bits.

Accordingly, one bit included in each of groups X₃₅, X₃₇, X₁₆ and X₂ constitute a single modulation symbol.

According to an exemplary embodiment, one bit included in each of the groups X₃₅, X₃₇, X₁₆ and X₂ constitute a single modulation symbol based on group interleaving and block interleaving. In addition to the above-described method, other methods for constituting a single modulation symbol with one bit included in each of the groups X₃₅, X₃₇, X₁₆ and X₂ may be included in the inventive concept.

The transmitting apparatus 100 may modulate a signal mapped onto a constellation and may transmit the signal to a receiving apparatus (for example, a receiving apparatus 2700 of FIG. 24). For example, the transmitting apparatus 100 may map a signal mapped onto a constellation onto an Orthogonal Frequency Division Multiplexing (OFDM) frame by using the OFDM method, and may transmit the signal to the receiving apparatus 2700 via an allocated channel.

To achieve this, the transmitting apparatus 100 may further include a frame mapper (not shown) to map the signal mapped onto the constellation onto the OFDM frame, and a transmitter (not shown) to transmit the signal of the OFDM frame format to the receiving apparatus 2700.

Case in Which a Block-Row Interleaver is Used

According to another exemplary embodiment, the interleaver 120 may interleave an LDPC codeword in other methods, different from the methods described in the exemplary embodiment 1 above, and may map bits included in a predetermined group from among a plurality of groups constituting the interleaved LDPC codeword onto a predetermined bit of a modulation symbol. This will be explained in detail with reference to FIG. 20.

Referring to FIG. 20, the interleaver 120 includes a parity interleaver 121, a group interleaver (or a group-wise interleaver 122), a group twist interleaver 123 and a block-row interleaver 125. Herein, the parity interleaver 121 and the group twist interleaver 123 perform the same functions as in the exemplary embodiment 1 described above, and thus, a detailed description of these elements is omitted.

The group interleaver 122 may divide a parity-interleaved LDPC codeword into a plurality of groups, and may rearrange the order of the plurality of groups.

In this case, the operation of dividing the parity-interleaved LDPC codeword into the plurality of groups is the same as in the exemplary embodiment 1, and thus, a detailed description thereof is omitted.

The group interleaver 122 interleaves an LDPC codeword in group units. That is, the group interleaver 122 may rearrange the order of the plurality of groups in the LDPC codeword in group units by changing locations of the plurality of groups constituting the LDPC codeword.

In this case, the group interleaver 122 may interleave the LDPC codeword in group units by using Equation 12

Y _(j) =X _(π(j)) (0≤j<N _(group))   (12),

where X_(j) is the j^(th) group before group interleaving, and Y_(j) is the j^(th) group after group interleaving. In addition, π(j) is a parameter indicating an interleaving order and is determined by at least one of a length of an LDPC codeword, a code rate and a modulation method.

Accordingly, X_(π(j)) is a π(j)^(th) group before group interleaving, and Equation 13 means that the pre-interleaving π(j)^(th) group is interleaved into the j^(th) group.

According to an exemplary embodiment, an example of π(j) may be defined as in Tables 47 to 51 presented below.

In this case, π(j) is defined according to a length of an LPDC codeword and a code rate, and a parity check matrix is also defined according to a length of an LDPC codeword and a code rate. Accordingly, when LDPC encoding is performed based on a specific parity check matrix according to a length of an LDPC codeword and a code rate, the LDPC codeword may be interleaved in group units based on π(j) satisfying the corresponding length of the LDPC codeword and code rate.

For example, when the encoder 110 performs LDPC encoding at a code rate of 10/15 to generate an LDPC codeword of a length of 16200, the group interleaver 122 may perform interleaving by using π(j) which is defined according to the length of the LDPC codeword of 16200 and the code rate of 10/15 in tables 47 to 51 presented below.

For example, when the length of the LDPC codeword is 16200, the code rate is 10/15, and the modulation method is 16-QAM, the group interleaver 122 may perform interleaving by using π(j) defined as in table 47.

An example of π(j) is as follows:

For example, when the length N_(ldpc) of the LDPC codeword is 16200, the code rate is 10/15, 11/15, 12/15 and 13/15, and the modulation method is 16-QAM, π(j) may be defined as in Table 47 presented below:

In the case of Table 47, Equation 12 may be expressed as X₀=Y_(π(0))=Y₁₁, X₁=Y_(π(1))=Y₃₈, X₂=Y_(π(2))=Y₂₇, . . . , X₄₃=Y_(π(43))=Y₁₇, and X₄₄=Y_(π(44))=Y₄₄. Accordingly, the group interleaver 122 may rearrange the order of the plurality of groups in group units by changing the 0^(th) group to the 11^(th) group, the 1^(st) group to the 38^(th) group, the 2^(nd) group to the 27^(th) group, . . . , the 43^(th) group to the 17^(th) group, and the 44^(th) group to the 44^(th) group.

In another example, when the length N_(ldpc) of the LDPC codeword is 16200, the code rate is 6/15, 7/15, 8/15 and 9/15, and the modulation method is 64-QAM, π(j) may be defined as in Table 48 presented below:

In the case of Table 48, Equation 12 may be expressed as X₀=Y_(π(0))=Y₂₆, X₁=Y_(π(1))=Y₂₂, X₂=Y_(π(2))=Y₄₁, . . . , X₄₃=Y_(π(43))=Y₄₃, and X₄₄=Y_(π(44))=Y₄₄. Accordingly, the group interleaver 122 may rearrange the order of the plurality of groups in group units by changing the 0^(th) group to the 26^(th) group, the 1^(st) group to the 22^(nd) group, the 2^(nd) group to the 41^(th) group, . . . , the 43^(rd) group to the 43^(rd) group, and the 44^(th) group to the 44^(th) group.

In another example, when the length N_(ldpc) of the LDPC codeword is 16200, the code rate is 10/15, 11/15, 12/15 and 13/15, and the modulation method is 256-QAM, π(j) may be defined as in Table 49 presented below:

In the case of Table 49, Equation 12 may be expressed as X₀=Y_(π(0))=Y₃₂, X₁=Y_(π(1))=Y₂₆, X₂=Y_(π(2))=Y₁₄, . . . , X₄₃=Y_(π(43))=Y₄₃, and X₄₄=Y_(π(44))=Y₄₄. Accordingly, the group interleaver 122 may rearrange the order of the plurality of groups in group units by changing the 0^(th) group to the 32^(nd) group, the 1^(st) group to the 26^(th) group, the 2^(nd) group to the 14^(th) group, . . . , the 43^(rd) group to the 43^(rd) group, and the 44^(th) group to the 44^(th) group.

In another example, when the length N_(ldpc) of the LDPC codeword is 16200, the code rate is 6/15, 7/15, 8/15 and 9/15, and the modulation method is 1024-QAM, π(j) may be defined as in Table 50 presented below:

In the case of Table 50, Equation 12 may be expressed as X₀=Y_(π(0))=Y₂₂, X₁=Y_(π(1))=Y₂₀, X₂=Y_(π(2))=Y₇, . . . , X₄₃=Y_(π(43))=Y₄₃, and X₄₄=Y_(π(44))=Y₄₄. Accordingly, the group interleaver 122 may rearrange the order of the plurality of groups in group units by changing the 0^(th) group to the 22^(nd) group, the 1^(st) group to the 20^(th) group, the 2^(nd) group to the 7^(th) group, . . . , the 43^(rd) group to the 43^(rd) group, and the 44^(th) group to the 44^(th) group.

In another example, when the length N_(ldpc) of the LDPC codeword is 64800, the code rate is 6/15, 7/15, 8/15 and 9/15, and the modulation method is 256-QAM, π(j) may be defined as in Table 51 presented below:

In the case of Table 51, Equation 12 may be expressed as X₀=Y_(π(0))=Y₇₂, X₁=Y_(π(1))=Y₄₈, X₂=Y_(π(2))=Y₅₅, . . . , X₁₇₈=Y_(π(178))=Y₁₇₈, and X₁₇₉=Y_(π(179))=Y₁₇₉. Accordingly, the group interleaver 122 may rearrange the order of the plurality of groups in group units by changing the 0^(th) group to the 72^(nd) group, the 1^(st) group to the 48^(th) group, the 2^(nd) group to the 55^(th) group, . . . , the 178^(th) group to the 178^(th) group, and the 179^(th) group to the 179^(th) group.

As described above, the group interleaver 122 may rearrange the order of the plurality of groups in group units by using Equation 12 and Tables 47 to 51.

On the other hand, since the order of the groups constituting the LDPC codeword is rearranged in group units by the group interleaver 122, and then, the groups are block-interleaved by the block interleaver 124, which will be described below, “Order of bits groups to be block interleaved” is set forth in Tables 47 to 51 in relation to π(j).

When the group interleaving is performed based on tables 47 to 51 as described above, the order of the groups constituting the group-interleaved LDPC codeword is different from that of the groups constituting the LDPC code group-interleaved based on tables 21 to 26.

This is because the block-row interleaver 125 is used in the present exemplary embodiment instead of the block interleaver 124 in FIG. 4. That is, since the interleaving method used in the block interleaver 124 and the interleaving method used in the block-row interleaver 125 are different from each other, the group interleaver 122 of the present exemplary embodiment rearranges the order of the plurality of groups constituting the LDPC codeword based on tables 47 to 51.

Specifically, the group interleaver 122 may rearrange the order of the plurality of groups in such that that an arrangement unit, in which at least one group including bits to be mapped onto the same modulation symbol is serially arranged in group units, is repeated.

That is, the group interleaver 122 may serially arrange one of a plurality of first groups including bits to be mapped onto a first specific location of each modulation symbol, one of a plurality of second groups including bits to be mapped onto a second specific location of each modulation symbol, . . . , one of a plurality of n^(th) groups including bits to be mapped onto an n^(th) specific location of each modulation symbol, and may arrange the other groups repeatedly in the same method.

The block-row interleaver 125 interleaves the plurality of groups the order of which has been rearranged. In this case, the block-row interleaver 125 may interleave the plurality of groups the order of which has been rearranged in group units by using at least one row including a plurality of columns. This will be explained in detail below with reference to FIGS. 21 to 23.

FIGS. 21 to 23 are views to illustrate a configuration of a block-row interleaver and an interleaving method according to an exemplary embodiment.

First, when N_(group)/m is an integer, the block-row interleaver 125 includes an interleaver 125-1 including m number of rows each including M number of columns as shown in FIG. 21, and the block-row interleaver 125 may interleave by using N_(group)/m number of interleavers 125-1 having the configuration of FIG. 21.

Herein, N_(group) is the total number of groups constituting an LDPC codeword. In addition, M is the number of bits included in a single group and may be 360, for example. m may be identical to the number of bits constituting a modulation symbol or may be ½ of the number of bits constituting a modulation symbol. For example, when a non-uniform QAM is used, performance of the bits constituting a modulation symbol is different, and thus, by setting m to be identical to the number of bits constituting a modulation symbol, a single group can be mapped onto a single bit of the modulation symbol.

Specifically, the block-row interleaver 125 may interleave by writing each of a plurality of groups constituting an LDPC codeword in each row in the row direction in group units, and reading each column of the plurality of rows in which the plurality of groups are written in group units in the column direction.

For example, as shown in FIG. 21, the block-row interleaver 125 writes m number of continuous groups from among the plurality of groups in each of the m number of rows of the interleaver 125-1 in the row direction, and reads each column of m number of rows in which bits are written in the column direction. In this case, as many interleavers 125-1 as the number of groups divided by the number of rows, that is, N_(group)/m, may be used.

As described above, when the number of groups constituting an LDPC codeword is an integer multiple of the number of rows, the block-row interleaver 125 may interleave by writing as many groups as the number of rows from among a plurality of groups constituting the LDPC codeword serially.

On the other hand, when the number of groups constituting an LDPC codeword is not an integer multiple of the number of rows, the block-row interleaver 125 interleaves by using N number of interleavers (N is an integer greater than or equal to 2) including different number of columns.

For example, as shown in FIGS. 22 and 23, the block-row interleaver 125 may interleave by using a first interleaver 125-2 including m number of rows each including M number of columns, and a second interleaver 125-3 including m number of rows each including a×M/m number of columns. Herein, a is N_(group)−└N_(group)/m┘×m, and └N_(group)/m┘ is the largest integer below N_(group)/m.

In this case, the first interleaver 125-2 may be used as many as └N_(group)/m┘ and one second interleaver 125-3 may be used.

Specifically, the block-row interleaver 125 may interleave a plurality of groups constituting an LDPC codeword by writing each of └N_(group)/m┘×m number of groups from among the plurality of groups constituting the LDPC codeword in each row in the row direction in group units, and reading each column of the plurality of rows in which └N_(group)/m┘×m number of groups are written in group units in the column direction.

For example, as shown in FIGS. 22 and 23, the block-row interleaver 125 may write the same m number of continuous groups as the number of rows from among └N_(group)/m┘×m number of groups in each row of the first interleaver 125-2 in the row direction, and may read each column of the plurality of rows of the first interleaver 125-2 in which m number of groups are written in the column direction. In this case, the first interleaver 125-2 having the configuration FIGS. 22 and 23 may be used as many as └_(group)/m┘.

In addition, in the case of a system using a plurality of antennas, m may be a product of the number of bits constituting a modulation method and the number of antennas

Thereafter, the block-row interleaver 125 may divide bits included in the other groups except the groups written in the first interleaver 125-2, and may write these bits in each row of the second interleaver 125-3 in the row direction. In this case, the same number of bits are written in each row of the second interleaver 125-3. That is, a single bit group may be input to the plurality of rows of the second interleaver 125-3.

For example, as shown in FIG. 22, the block-row interleaver 125 may write a×M/m number of bits from among the bits included in the other groups except the groups written in the first interleaver 125-2 in each of m number of rows of the second interleaver 125-3 in the row direction, and may read each column of m number of rows of the second interleaver 125-3 in which the bits are written in the column direction. In this case, one second interleaver 125-3 having the configuration of FIG. 22 may be used.

However, according to another exemplary embodiment, as shown in FIG. 23, the block-row interleaver 125 may write the bits in the first interleaver 125-2 in the same method as explained in FIG. 22, but may write the bits in the second interleaver 125-3 in a method different from that of FIG. 22.

That is, the block-row interleaver 125 may write the bits in the second interleaver 125-3 in the column direction.

For example, as shown in FIG. 23, the block-row interleaver 125 may write the bits included in the other groups except the groups written in the first interleaver 125-2 in each column of m number of rows each including a×M/m number of columns of the second interleaver 125-3 in the column direction, and may read each column of m number of rows of the second interleaver 125-3 in which the bits are written in the column direction. In this case, one second interleaver 125-3 having the configuration of FIG. 23 may be used.

In the method shown in FIG. 23, the block-row interleaver 125 interleaves by reading in the column direction after writing the bits in the second interleaver in the column direction. Accordingly, the bits included in the groups interleaved by the second interleaver are read in the order they were written and output to the modulator 130. Accordingly, the bits included in the groups belonging to the second interleaver are not rearranged by the block-row interleaver 125 and may be mapped onto the modulation symbols serially.

As described above, the block-row interleaver 125 may interleave the plurality of groups of the LDPC codeword by using the methods described above with reference to FIGS. 21 to 23.

According to the above-described method, the output of the block-row interleaver 125 may be the same as the output of the block interleaver 124. Specifically, when the block-row interleaver 125 interleaves as shown in FIG. 21, the block-row interleaver 125 may output the same value as that of the block interleaver 124 which interleaves as shown in FIG. 8. In addition, when the block-row interleaver 125 interleaves as shown in FIG. 22, the block-row interleaver 125 may output the same value as that of the block interleaver 124 which interleaves as shown in FIG. 9. In addition, when the block-row interleaver 125 interleaves as shown in FIG. 23, the block-row interleaver 125 may output the same value as that of the block interleaver 124 which interleaves as shown in FIG. 10.

Specifically, when the group interleaver 122 is used based on Equation 11 and the block interleaver 124 is used, and the output groups of the group interleaver 122 are Y_(i) (0≤j<N_(group)) and when the group interleaver 122 is used based on Equation 12 and the block-row interleaver 125 is used, and the output groups of the group interleaver 122 are Z_(i) (0≤j<N_(group)), a relationship between the output groups Z_(i) and Y_(i) after group interleaving may be expressed as in Equations 13 and 14, and as a result, the same value may be output from the block interleaver 124:

Z _(i+m×j) =Y _(α×i+j) (0≤i<m,0≤j<α)   (13)

Z _(i) =Y _(i)(α×m≤i<N _(group))   (14),

where α is └N_(group)/m┘ and is the number of groups written in a single column of the first part when the block interleaver 124 is used, and └N_(group)/m┘ is the largest integer below N_(group)/m. Here, m is identical to the number of bits constituting a modulation symbol or half of the bits constituting a modulation symbol. In addition, m is the number of columns of the block interleaver 124 and m is the number of rows of the block-row interleaver 125.

Accordingly, the modulator 130 may map the bits output from the block-row interleaver 125 onto a modulation symbol in the same method as when the block interleaver 124 is used.

The bit interleaving method suggested in the exemplary embodiments is performed by the parity interleaver 121, the group interleaver 122, the group twist interleaver 123, and the block interleaver 124 as shown in FIG. 4 (the parity interleaver 121 or group twist interleaver 123 may be omitted according to circumstances). However, this is merely an example and the bit interleaving method is not limited to three modules or four modules described above.

For example, when the block interleaver is used and the group interleaving method expressed as in Equation 11 is used, regarding the bit groups X_(j) (0≤j<N_(group)) defined as in Equation 9 and Equation 10, bits belonging to m number of bit groups, for example, {X_(π(i)), X_(π(α+i)), . . . ,X_(π((m−1)×α+i))} (0≤i<α), may constitute a single modulation symbol.

Herein, α is the number of bit groups constituting the first part of the block interleaver, and α=└N_(group)/m┘. In addition, m is the number of columns of the block interleaver and may be equal to the number of bits constituting the modulation symbol or half of the number of bits constituting the modulation symbol.

Therefore, for example, regarding parity-interleaved bits u_(i), {u_(π(i)+j), u_(π(α+i)+j), . . . ,u_(π((m−1)×α+i)+j)} (0<i≤m, 0<j≤M) may constitute a single modulation symbol. As described above, there are various methods for constituting a single modulation symbol.

In addition, the bit interleaving method suggested in the exemplary embodiments is performed by the parity interleaver 121, the group interleaver 122, the group twist interleaver 123, and the block-row interleaver 125 as shown in FIG. 20 (the group twist interleaver 123 may be omitted according to circumstances). However, this is merely an example and the bit interleaving method is not limited to three modules or four modules described above.

For example, when the block-row interleaver is used and the group interleaving method expressed as in Equation 12 is used, regarding the bit groups X_(j) (0≤j<N_(group)) defined as in Equation 9 and Equation 10, bits belonging to m number of bit groups, for example, {X_(π(m×i)), X_(π(m×i+1)), . . . ,X_(π(m×i+(m−1)))} (0≤i<α), may constitute a single modulation symbol.

Herein, α is the number of bit groups constituting the first part of the block interleaver, and α=└N_(group)/m┘. In addition, m is the number of columns of the block interleaver and may be equal to the number of bits constituting the modulation symbol or half of the number of bits constituting the modulation symbol.

Therefore, for example, regarding parity-interleaved bits u_(i), {u_(π(m×i)+j), u_(π(m×i+1)+j), . . . ,u_(π(m×i+(m−1))+j)} (0<i≤m, 0<j≤M) may constitute a single modulation symbol. As described above, there are various methods for constituting a single modulation symbol.

Hereinafter, a method for determining π(j) which is a parameter used for group interleaving according to various exemplary embodiments will be explained.

Hereinafter, a method for designing the group interleaver 122 of FIG. 4 or 20 will be explained.

Step 1): An LDPC code set for applying group interleaving is determined (that is, the LDPC code set is expressed as a code rate and is indicated by R₁, R₂, . . . , R_(max), and is set to satisfy a relationship of R₁<R₂<R₃< . . . ).

For example, when a same group interleaving pattern is applied to LDPC codes having code rates of R₁=5/15, R₂=6/15, R₃=7/15, R₄=8/15, R₅=9/15 and a length of 64800, an LDPC code set having a code rate of R₁=5/15, R₂=6/15, R₃=7/15, R₄=8/15, R₅=9/15 is determined. When different group interleaving is applied according to each LDPC code having its own length and code rate, each LDPC code may be determined as an LDPC code set.

Step 2): Regarding the LDPC code having the lowest code rate R₁ in the LDPC code set determined in step 1, mapping profiles satisfying a given condition for a defined threshold through a theoretical performance analyzing method of Density Evolution and selected from profiles for mapping a modulation symbol according to a degree of column of an LDPC code is set by considering degree of reliability of bits constituting a modulation symbol.

Step 3): When mapping profiles for the LDPC code having the second lowest code rate R₂ are obtained by selecting one of the mapping profiles determined for the LDPC code having the lowest code rate R₁ in step 2, mapping profiles for R₂ are determined to satisfy the condition that the mapping profiles for R₁ is maintained to the maximum.

When mapping profiles selected for the LDPC code having the code rate R_((i+1)), the mapping profiles are determined to satisfy the condition that mapping profiles selected for R_(i) is maintained to the maximum (i=1, 2, . . . ).

Step 4): The process in step 3 is repeated for all code rates and then performance verification is performed for a plurality of finally selected mapping profiles, and a group interleaver is determined for the best mapping profile.

In the above-described method, the group interleaver 122 of FIG. 4 or 20 may be designed.

FIG. 24 is a block diagram to illustrate a configuration of a receiving apparatus according to an exemplary embodiment. Referring to FIG. 24, the receiving apparatus 2700 includes a demodulator 2710, a multiplexer 2720, a deinterleaver 2730 and a decoder 2740.

The demodulator 2710 receives and demodulates a signal transmitted from the transmitting apparatus 100. Specifically, the demodulator 2710 generates a value corresponding to an LDPC codeword by demodulating the received signal, and outputs the value to the multiplexer 2720. In this case, the demodulator 2710 may use a demodulation method corresponding to a modulation method used in the transmitting apparatus 100.

The value corresponding to the LDPC codeword may be expressed as a channel value for the received signal. There are various methods for determining the channel value, and for example, a method for determining a Log Likelihood Ratio (LLR) value may be the method for determining the channel value.

The LLR value is a log value for a ratio of the probability that a bit transmitted from the transmitting apparatus 100 is 0 and the probability that the bit is 1. In addition, the LLR value may be a bit value which is determined by a hard decision, or may be a representative value which is determined according to a section to which the probability that the bit transmitted from the transmitting apparatus 100 is 0 or 1 belongs.

The multiplexer 2720 multiplexes the output value of the demodulator 2710 and outputs the value to the deinterleaver 2730.

Specifically, the multiplexer 2720 is an element corresponding to a demultiplexer (not shown) provided in the transmitting apparatus 100, and performs an operation corresponding to the demultiplexer (not shown). Accordingly, when the demultiplexer (not shown) is omitted from the transmitting apparatus 100, the multiplexer 2720 may be omitted from the receiving apparatus 2700.

That is, the multiplexer 2720 converts the output value of the demodulator 2710 into cell-to-bit and outputs an LLR value on a bit basis.

In this case, when the demultiplexer (not shown) does not change the order of the LDPC codeword bits as shown in FIG. 13, the multiplexer 2720 may output the LLR values serially on the bit basis without changing the order of the LLR values corresponding to the bits of the cell. Alternatively, the multiplexer 2720 may rearrange the order of the LLR values corresponding to the bits of the cell to perform an inverse operation to the demultiplexing operation of the demultiplexer (not shown) based on Table 32.

The deinterleaver 2730 deinterleaves the output value of the multiplexer 2720 and outputs the values to the decoder 2740.

Specifically, the deinterleaver 2730 is an element corresponding to the interleaver 120 of the transmitting apparatus 100 and performs an operation corresponding to the interleaver 120. That is, the deinterleaver 2730 deinterleaves the LLR value by performing the interleaving operation of the interleaver 120 inversely.

In this case, the deinterleaver 2730 may include elements as shown in FIGS. 25 and 27.

First, as shown in FIG. 25, the deinterleaver 2730 includes a block deinterleaver 2731, a group twist deinterleaver 2732, a group deinterleaver 2733, and a parity deinterleaver 2734, according to an exemplary embodiment.

The block deinterleaver 2731 deinterleaves the output of the multiplexer 2720 and outputs a value to the group twist deinterleaver 2732.

Specifically, the block deinterleaver 2731 is an element corresponding to the block interleaver 124 provided in the transmitting apparatus 100 and performs the interleaving operation of the block interleaver 124 inversely.

That is, the block deinterleaver 2731 deinterleaves by using at least one row formed of a plurality of columns, that is, by writing the LLR value output from the multiplexer 2720 in each row in the row direction and reading each column of the plurality of rows in which the LLR value is written in the column direction.

In this case, when the block interleaver 124 interleaves by dividing a column into two parts, the block deinterleaver 2731 may deinterleave by dividing a row into two parts.

In addition, when the block interleaver 124 performs writing and reading with respect to a group which does not belong to the first part in the row direction, the block deinterleaver 2731 may deinterleave by writing and reading a value corresponding to the group which does not belong to the first part in the row direction.

Hereinafter, the block deinterleaver 2731 will be explained with reference to FIG. 26. However, this is merely an example and the block deinterleaver 2731 may be implemented in other methods.

An input LLR v_(i) (0≤i<N_(ldpc)) is written in a r_(i) row and a c_(i) column of the block deinterleaver 2431. Herein, c_(i)=(i mod N_(c)) and

${r_{i} = \left\lfloor \frac{i}{N_{c}} \right\rfloor},$

On the other hand, an output LLR q_(i) (0≤i<N_(c)×N_(r1)) is read from a c_(i) column and a r_(i) row of the first part of the block deinterleaver 2431. Herein,

${c_{i} = \left\lfloor \frac{i}{N_{r\; 1}} \right\rfloor},$

r_(i)=(i mod N_(r1))

In addition, an output LLR q_(i)(N_(c)×N_(r1)≤i<N_(ldpc)) is read from a c_(i) column and a r_(i) row of the second part. Herein,

${c_{i} = \left\lfloor \frac{\left( {i - {N_{c} \times N_{r\; 1}}} \right)}{N_{r\; 2}} \right\rfloor},$

r_(i)=N_(r1)+{(i−N_(c)×N_(r1)) mode N_(r2)}.

The group twist deinterleaver 2732 deinterleaves the output value of the block deinterleaver 2731 and outputs the value to the group deinterleaver 2733.

Specifically, the group twist deinterleaver 2732 is an element corresponding to the group twist interleaver 123 provided in the transmitting apparatus 100, and may perform the interleaving operation of the group twist interleaver 123 inversely.

That is, the group twist deinterleaver 2732 may rearrange the LLR values of the same group by changing the order of the LLR values existing in the same group. When the group twist operation is not performed in the transmitting apparatus 100, the group twist deinterleaver 2732 may be omitted.

The group deinterleaver 2733 (or the group-wise deinterleaver) deinterleaves an output value of the group twist deinterleaver 2732 and outputs a value to the parity deinterleaver 2734.

Specifically, the group deinterleaver 2733 is an element corresponding to the group interleaver 122 provided in the transmitting apparatus 100 and may perform the interleaving operation of the group interleaver 122 inversely.

That is, the group deinterleaver 2733 may rearrange the order of the plurality of groups in group units. In this case, the group deinterleaver 2733 may rearrange the order of the plurality of groups in group units by applying the interleaving method of Tables 21 to 26 inversely according to a length of the LDPC codeword, a modulation method and a code rate.

As described above, in the parity check matrix having the format shown in FIGS. 2 and 3, the order of column groups is changeable and the column group corresponds to a bit group. Accordingly, when the order of column groups of the parity check matrix is changed, the order of bit groups is changed accordingly and the group deinterleaver 2733 may rearrange the order of the plurality of groups in group units with reference to this.

The parity deinterleaver 2734 performs parity deinterleaving with respect to an output value of the group deinterleaver 2733 and outputs a value to the decoder 2740.

Specifically, the parity deinterleaver 2734 is an element corresponding to the parity interleaver 121 provided in the transmitting apparatus 100 and may perform the interleaving operation of the parity interleaver 121 inversely. That is, the parity deinterleaver 2734 may deinterleave the LLR values corresponding to the parity bits from among the LLR values output from the group deinterleaver 2733. In this case, the parity deinterleaver 2734 may deinterleave the LLR values corresponding to the parity bits in an inverse method of the parity interleaving method of Equation 8.

However, the parity deinterleaving is performed only when the transmitting apparatus 100 generates the LDPC codeword using the parity check matrix 200 as shown in FIG. 2. The parity deinterleaver 2734 may be omitted when the LDPC codeword is encoded based on the parity check matrix 300 as shown in FIG. 3. In addition, even when the LDPC codeword is generated by using the parity check matrix 200 of FIG. 2, LDPC decoding may be performed based on the parity check matrix 300 of FIG. 3. In this case, the parity deinterleaver 2734 may be omitted.

Although the deinterleaver 2730 of FIG. 24 includes three (3) or four (4) elements as shown in FIG. 25, operations of the elements may be performed by a single element. For example, when bits each of which belongs to each of bit groups X_(a), X_(b), X_(c), and X_(d) constitute a single modulation symbol, the deinterleaver may deinterleave these bits to locations corresponding to their bit groups based on the received single modulation symbol.

For example, when a code rate is 12/15 and a modulation method is 16-QAM, the group deinterleaver 2733 may perform deinterleaving based on table 21.

In this case, bits each of which belongs to each of bit groups X₃₅, X₃₇, X₁₆, and X₂ constitute a single modulation symbol. Since one bit in each of the bit groups X₃₅, X₃₇, X₁₆, and X₂ constitutes a single modulation symbol, the deinterleaver 2730 may map bits onto decoding initial values corresponding to the bit groups X₃₅, X₃₇, X₁₆, and X₂ based on the received single modulation symbol.

The deinterleaver 2730 may include a block-row deinterleaver 2735, a group twist deinterleaver 2732, a group deinterleaver 2733 and a parity deinterleaver 2734, as shown in FIG. 27. In this case, the group twist deinterleaver 2732 and the parity deinterleaver 2734 perform the same functions as in FIG. 25, and thus, a redundant explanation is omitted.

The block-row deinterleaver 2735 deinterleaves an output value of the multiplexer 2720 and outputs a value to the group twist deinterleaver 2732.

Specifically, the block-row deinterleaver 2735 is an element corresponding to the block-row interleaver 125 provided in the transmitting apparatus 100 and may perform the interleaving operation of the block-row interleaver 125 inversely.

That is, the block-row deinterleaver 2735 may deinterleave by using at least one column formed of a plurality of rows, that is, by writing the LLR values output from the multiplexer 2720 in each column in the column direction and reading each row of the plurality of columns in which the LLR value is written in the column direction.

However, when the block-row interleaver 125 performs writing and reading with respect to a group which does not belong to the first part in the column direction, the block-row deinterleaver 2735 may deinterleave by writing and reading a value corresponding to the group which does not belong to the first part in the column direction.

The group deinterleaver 2733 deinterleaves the output value of the group twist deinterleaver 2732 and outputs the value to the parity deinterleaver 2734.

Specifically, the group deinterleaver 2733 is an element corresponding to the group interleaver 122 provided in the transmitting apparatus 100 and may perform the interleaving operation of the group interleaver 122 inversely.

That is, the group deinterleaver 2733 may rearrange the order of the plurality of groups in group units. In this case, the group deinterleaver 2733 may rearrange the order of the plurality of groups in group units by applying the interleaving method of Tables 47 to 51 inversely according to a length of the LDPC codeword, a modulation method and a code rate.

Although the deinterleaver 2730 of FIG. 24 includes three (3) or four (4) elements as shown in FIG. 27, operations of the elements may be performed by a single element. For example, when bits each of which belongs to each of bit groups X_(a), X_(b), X_(c), and X_(d) constitute a single modulation symbol, the deinterleaver 2730 may deinterleave these bits to locations corresponding to their bit groups based on the received single modulation symbol.

The decoder 2740 may perform LDPC decoding by using the output value of the deinterleaver 2730. To achieve this, the decoder 2740 may include a separate LDPC decoder (not shown) to perform the LDPC decoding.

Specifically, the decoder 2740 is an element corresponding to the encoder 110 of the transmitting apparatus 200 and may correct an error by performing the LDPC decoding by using the LLR value output from the deinterleaver 2730.

For example, the decoder 2740 may perform the LDPC decoding in an iterative decoding method based on a sum-product algorithm. The sum-product algorithm is one example of a message passing algorithm, and the message passing algorithm refers to an algorithm which exchanges messages (e.g., LLR value) through an edge on a bipartite graph, calculates an output message from messages input to variable nodes or check nodes, and updates.

The decoder 2740 may use a parity check matrix when performing the LDPC decoding. In this case, an information word submatrix in the parity check matrix is defined as in Tables 4 to 20 according to a code rate and a length of the LDPC codeword, and a parity submatrix may have a dual diagonal configuration.

In addition, information on the parity check matrix and information on the code rate, etc. which are used in the LDPC decoding may be pre-stored in the receiving apparatus 2700 or may be provided by the transmitting apparatus 100.

FIG. 28 is a flowchart to illustrate a signal processing method according to an exemplary embodiment.

First of all, an LDPC codeword is generated by performing LDPC encoding (S3010).

Subsequently, the LDPC codeword is interleaved (S3020). In this case, using a plurality of columns including a plurality of rows respectively, the plurality of columns may be divided into two parts, and the LDPC codeword may be interleaved.

A modulation symbol is generated by modulating the LDPC codeword which is interleaved according to a modulation method (S3030).

Meanwhile, in S3020, the plurality of columns may be divided into a first part and a second part, and the interleaving may be performed as the LDPC codeword is written and read using the same method in the first part and the second part. To be specific, the interleaving may be performed by writing the LDPC codeword in a plurality of columns constituting each of the first part and the second part in a column direction and reading a plurality of columns constituting each of the first part and the second part where the LDPC codeword is written in a row direction.

In addition, in S3020, a plurality of columns may be divided into the first part and the second part based on the number of columns.

Herein, the first part may be formed of as many rows as the number of bits included in at least one group which can be written in each column in group units from among the plurality of groups of the LDPC codeword, according to the number of columns constituting the block interleaver 124 and the number of bits constituting each of the plurality of groups. The second part may be formed of rows excluding as many rows as the number of bits included in at least some groups which can be written in each of the plurality of columns in group units.

Meanwhile, the number of columns may be determined according to a modulation method.

In addition, in S3020, the interleaving may be performed as at least some groups which can be written in each group of the plurality of columns in group units are written in each of the plurality of columns constituting the first part in a column direction, the groups excluding the at least some groups from among the plurality of groups are divided and written in each of the plurality of columns constituting the second part in a column direction, and the bits written in each of the plurality of columns consisting each of the first part and the second part are read in a row direction.

Herein, the groups excluding the at least some groups from among the plurality of groups may be divided based on the number of columns.

Meanwhile, the step of dividing the LDPC codeword into the plurality of groups and rearranging the order of the plurality of groups in group units may be further included. In this case, in S3020, the plurality of groups of which order is rearranged may be interleaved.

In this case, in S3030, a modulation symbol may be generated using bits included in each of the plurality of groups.

A non-transitory computer readable medium, which stores a program for performing the above signal processing methods according to various exemplary embodiments in sequence, may be provided.

The non-transitory computer readable medium refers to a medium that stores data semi-permanently rather than storing data for a very short time, such as a register, a cache, and a memory, and is readable by an apparatus. Specifically, the above-described various applications or programs may be stored in a non-transitory computer readable medium such as a compact disc (CD), a digital versatile disk (DVD), a hard disk, a Blu-ray disk, a universal serial bus (USB), a memory card, and a read only memory (ROM), and may be provided.

Components, elements or units represented by a block as illustrated in FIGS. 1, 4, 12, 13, 23 and 27-29 may be embodied as the various numbers of hardware, software and/or firmware structures that execute respective functions described above, according to exemplary embodiments. For example, these components, elements or units may use a direct circuit structure, such as a memory, processing, logic, a look-up table, etc. that may execute the respective functions through controls of one or more microprocessors or other control apparatuses. These components, elements or units may be specifically embodied by a module, a program, or a part of code, which contains one or more executable instructions for performing specified logic functions. Also, at least one of the above components, elements or units may further include a processor such as a central processing unit (CPU) that performs the respective functions, a microprocessor, or the like.

Although a bus is not illustrated in the block diagrams of the transmitting apparatus and the receiving apparatus, communication may be performed between each element of each apparatus via the bus. In addition, each apparatus may further include a processor such as a Central Processing Unit (CPU) or a microprocessor to perform the above-described various operations.

The foregoing exemplary embodiments and advantages are merely exemplary and are not to be construed as limiting the present inventive concept. The exemplary embodiments can be readily applied to other types of apparatuses. Also, the description of the exemplary embodiments is intended to be illustrative, and not to limit the scope of the inventive concept, and many alternatives, modifications, and variations will be apparent to those skilled in the art. 

What is claimed is:
 1. A broadcast signal transmitting method comprising: encoding input bits to generate parity bits based on a low density parity check (LDPC) code, splitting a codeword comprising the input bits and the parity bits into bit groups, interleaving the bit groups based on a predetermined interleaving order, wherein the predetermined interleaving order is obtained based on a code rate of the LDPC code, writing bits of the interleaved bit groups in columns, each of the columns comprising a first part and a second part, reading the written bits from the columns, mapping the read bits onto constellation points which are based on a modulation method, and generating a broadcast signal based on the constellation points using orthogonal frequency division multiplexing (OFDM) scheme, and transmitting the broadcast signal, wherein the modulation method is one of quadrature phase shift keying (QPSK), quadrature amplitude modulation (QAM), 64-QAM and 256-QAM, wherein at least one first bit group of the interleaved bit groups is interleaved in the first part and at least one second bit group of the interleaved bit groups is interleaved in the second part, and wherein the each of the columns is divided into the first part and the second part based on the modulation method for the mapping and a number of the bit groups.
 2. The transmitting method of claim 1, wherein each of the bit groups comprises 360 bits.
 3. The broadcast signal transmitting method of claim 1, further comprising: interleaving the parity bits; and splitting a codeword comprising the input bits and the interleaved parity bits into bit groups.
 4. The broadcast signal transmitting method of claim 1, wherein a length of the codeword is
 16200. 